98667 Clean and Improved Cooking in Sub-Saharan Africa November 2014 Second edition A Landscape Report Africa Renewable Energy Access Program (AFREA) Copyright © 2014 The World Bank 1818 H Street, N.W. Washington, D.C. 20433, U.S.A. All rights reserved The findings, interpretations, and conclusions expressed in this report are entirely those of the authors and should not be attributed in any manner to the World Bank or its affiliated organizations, or to members of its Board of Executive Directors or the countries they represent. The World Bank does not guarantee the accuracy of the data included in this publication and accepts no responsibility whatsoever for any consequence of their use. The material in this publication is copyrighted. The World Bank encourages dissemination of its work and will normally grant permission promptly. Cover photo: © ILF/Deborah Terry/2014 Photo page iv: © Klas Sander Design & layout: Geomark Development Ltd. Clean and Improved Cooking in Sub-Saharan Africa November 2014 Second edition A Landscape Report Acknowledgments This report was commissioned by the World Bank’s Energy & Extractives Practice (GEEDR), with the support of the Energy Sector Management Assistance Program (ESMAP) and the Africa Renewable Energy Access Program (AFREA). The project team comprised Srilata Kammila, Jan Kappen, Dana Rysankova, Besnik Hyseni, and Venkata Ramana Putti. The report relied on inputs from a wide cross-section of World Bank staff, numerous industry experts, manufacturers, distributors, policy makers, and nongovernmental organizations, including interviews with more than one hundred players in the clean and improved cooking energy sector in Africa and globally. Critical advisory/technical inputs have been provided by World Bank colleagues Koffi Ekouevi, Richard Hosier, Klas Sander, Masami Kojima, Laurent Durix, Yabei Zhang, Sudeshna Ghosh Banerjee, Mikul Bhatia, Joy Clancy, Christophe de Gouvello, and Sameer Akbar; Lasse Ringius, Luiz Maurer, and Pepukaye Bardouille from IFC; and Radha Muthiah, Sumi Mehta, Leslie Cordes, Ranyee Chiang, and Sean Bartlett from the Global Alliance for Clean Cookstoves. The final draft was reviewed by Koffi Ekouevi, Laurent Durix, Masami Kojima, and Klas Sander. Meike Van Ginneken, Practice Manager (West and Central Africa), provided valuable guidance. Dalberg Global Development Advisors (www.dalberg.com) acted as the consultants for the report. Their team was led by Michael Tsan (partner and lead report author) and comprised Gaurav Gupta, Jason Wendle, Paul Collett, Fauzia Jamal, Yaquta Kanchwala, Pallavi Jayannavar, Nicholas Whalley, Kira Intrator, Ibrahima Wade, Kathleen Wade, Ethan Kay, Neha Juneja, and Ankit Mathur. We are thankful to all sector participants and experts who have generously contributed their time to this endeavor. The World Bank team welcomes your support in this effort and encourages you to reach out to the report’s authors with your questions and feedback.  iv Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report CONTENTS Acknowledgments iv Figures 3 Abbreviations 5 Foreword 8 Executive Summary 12 Recommendations 15 Key Facts and Figures 17 1. The Case for Clean Cooking 19 The Harmful Effects of Solid-Fuel Cooking and Traditional Cookstoves 20 The Harm Mitigation Potential of Clean and Improved Cooking Solutions 26 2. Demand for Clean and Improved Cooking Solutions 35 Demand Landscape for Household Cooking Fuels 36 African Cooking Consumer Segmentation 41 Demand for Clean and Improved Cookstoves in SSA: Drivers and Constraints 46 African End-user Preferences for Stove Design and Performance 48 Willingness to Adopt and Pay for Improved and Clean Solutions 50 Affordability and Ability to Pay 52 Addressing Consumers’ Willingness to Pay 53 3. Supply of Clean and Improved Cooking Solutions 59 Penetration of Clean and Improved Stoves in Africa 60 Structure of the Cookstoves Manufacturing Sector 69 Fuel Supply Trends 74 Cookstove Costs and Sector Economics 76 Technology and Business Model Innovation 79 Clean and Improved Cooking Distribution Models 85 4. The Enabling Environment 89 Overview of the Cooking Ecosystem in Sub-Saharan Africa 90 National Programs 93 Challenges to the Enabling Environment 102 Funding for the SSA Cooking Sector 106 5. Looking Forward 109 Recommendations 114 Appendixes 125 Appendix 1: Overview of SSA Cooking Solutions 126 Appendix 2: IWA ISO Standards for Improved and Clean Cookstoves 133 Appendix 3: Methodology for Determining the Opportunity Cost of Cooking with Solid Fuels 134 Appendix 4: Methodology for Calculating SSA Fuel Mix and Fuel Mix Evolution 135 Appendix 5: SSA Fuel Mix—Latest Known, by Country 136 Appendix 6: Methodology for SSA Fuel Market Sizing and Forecast 140 Appendix 7: Methodology for Analyzing Emissions from Solid-Fuel Cooking 142 Appendix 8: Customer Segmentation Methodology 144 Appendix 9: Methodology for Analyzing ICS Penetration 147 Appendix 10: ICS Market Forecast 148 Appendix 11: Range of Performance, by Technology 149 Appendix 12: Fuel Prices by Geography 150 Appendix 13: Consumer Preferences, by Segment 152 Notes 153 Bibliography 168 2 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report FIGURES Figure 1: Overview of improved and clean cooking solutions 9 Figure 2: Sub-Saharan Africa mortality and morbidity, by risk factor (2010) 21 Figure 3: Relative incidence of HAP-related morbidity across Sub-Saharan Africa (2010) 21 Figure 4: Share of households cooking outdoors—select SSA countries 22 Figure 5: Cooking and lighting energy as a share of household expenditure 23 Figure 6: Time spent on firewood collection in Africa 23 Figure 7: Contribution of solid-fuel cooking to GHG and black carbon emissions in SSA 24 Figure 8: Biomass pressure map: solid-fuel cooking in Sub-Saharan Africa 25 Figure 9: Firewood collection and cooking time, by gender 26 Figure 10: Stove and fuel costs in Africa (2012) 28 Figure 11: Exposure response curve for particulate matter emissions (PM2.5) 29 Figure 12: Comparative performance of “average” stoves on health and climate impact dimensions 30 Figure 13: Relationship between cooking solution performance (HAP emissions) and cost 32 Figure 14: Solid- and modern-fuel usage, by global region (2010) 36 Figure 15: SSA primary cooking-fuel mix, by subregion and rural/urban area 37 Figure 16: Historical trends and forecast for the global solid-fuel population 39 Figure 17: Historical and projected SSA fuel mix 39 Figure 18: Historical fuel cost for the average household in SSA 40 Figure 19: SSA annual household spending on cooking fuels (US$ billions) 41 Figure 20: Segmentation of the SSA improved and clean cooking consumer 42 Figure 21: Firewood-purchasing households as a share of all firewood users in Sub-Saharan Africa 43 Figure 22: Key demand drivers of, and challenges to, SSA clean and improved cooking solutions 46 Figure 23: Stove design preferences of African consumers 48 Figure 24: Willingness to adopt or pay: examples of nonadopter populations after ICS exposure 51 Figure 25: Baseline technology persistence in African clean and improved stove programs 52 Figure 26: Increasing consumer willingness to pay through exposure 53 Figure 27: Approaches to improving consumers’ ability and willingness to pay 55 Figure 28: SSA population by cooking market segment (primary fuel) 56 Figure 29: Willingness and ability to pay by segment—example of two SSA villages 57 Figure 30: Overview of Africa clean and improved stove penetration (2010–2013) 61 Figure 31: Current Africa sales and forward-looking trends, by stove technology 62 Figure 32: Domestic LPG consumption for top SSA LPG markets 63 Figure 33: Africa briquette and pellet fuel business for household cooking 65 Figure 34: Africa ICS and ACS biomass stove mix (2011–2013) 65 Figure 35: ICS penetration among users of wood and charcoal stoves 67 Figure 36: Penetration of modern fuels and improved cookstoves, by SSA country (2010) 68 Figure 37: Clean and improved cookstove production models in Africa 69 Figure 38: ICS and renewable stove production models range from industrial, to semi-industrial, to artisanal 70 Figure 39: Distribution of Kenya Ceramic Jiko and comparable solutions across Africa 72 Figure 40: Select SSA industrial and semi-industrial clean and improved stove manufacturers (2014) 72 Figure 41: The industrial and semi-industrial ICS sector is highly fragmented, with only a handful of players globally exceeding 50k in sales 73 Figure 42: Fuel supply: challenges for the SSA charcoal supply chain 74 3 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Figure 43: Fuel supply market interventions example—improved charcoal kilns 75 Figure 44: Price and annual average cost for various cooking appliances 76 Figure 45: Detailed cost distribution for artisanal, semi-industrial, and industrial models 77 Figure 46: Impact of portable rocket stove production in Africa 78 Figure 47: Example of shifting natural-draft gasifier manufacturing to Africa semi-industrial production 78 Figure 48: Advanced biomass stove innovation—examples of ACS models for sale in Africa 80 Figure 49: TEG technology—BioLite example 82 Figure 50: Integrated fuel/stove model—the Inyenyeri example 83 Figure 51: Mobile-enabled, off-grid model for an energy utility—the Angaza example 84 Figure 52: Emerging distribution channels for clean cookstoves 85 Figure 53: Overview of Africa cookstove distribution models 86 Figure 54: Overview of the SSA landscape for clean and improved cooking stakeholders 91 Figure 55: Overview of SSA clean and improved national cookstove programs 93 Figure 56: Overview of SSA clean and improved national cookstove programs 94 Figure 57: Large regional cookstove programs in Africa 97 Figure 58: State of ICS carbon finance market (2013) 104 Figure 59: Clean and improved cookstove funding 105 Figure 60: Clean and improved cookstove funding 106 Figure 61: Base-case forecast for market growth (2010–20) 110 Figure 62: Barriers to the adoption of clean and improved cooking solutions 112 Figure 63: Overview of market barriers 113 Figure 64: Recommended approach for policy makers, by SSA consumer segment 115 Figure 65: Recommended approach for policy makers, by technology segment 116 4 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Abbreviations ABPP Africa Biogas Partnership Programme GHG greenhouse gas ACCES Africa Clean Cooking Energy Solutions GIZ Gesellschaft für Internationale ACS advanced [biomass] cookstoves Zusammenarbeit AEF Africa Energy Forum GLPGP Global Liquid Petroleum Gas Partnership AFREA Africa Renewable Energy Access Program GS gold standard ALRI acute lower respiratory infection GSM Global System for Mobile Communications AREED Africa Rural Energy Enterprise GVEP Global Village Energy Partnership Development GWP global warming potential BC black carbon HAP household air pollution BEIA Biomass Energy Initiative for Africa HH household bn billion ICEED International Centre for Energy, BoP base of the pyramid Environment, and Development BTU British thermal unit ICS improved [biomass] cookstove CAGR compounded annual growth rate ICT information and communications CBA cost-benefit analysis technology CBFM community-based forest management IEA International Energy Agency CDM clean development mechanism IFC International Finance Corporation CERs certified emission reductions ILF International Lifeline Fund CH4 methane IPCC Intergovernmental Panel on Climate CO carbon monoxide Change CO2e carbon dioxide-equivalent ISO International Organization for Standardization CO2-eq carbon dioxide-equivalent IWA International Workshop Agreement COPD chronic obstructive pulmonary disease k thousand DALY disability-adjusted life years KCJ Kenya Ceramic Jiko DEEP Developing Energy Enterprises Program kg kilogram DHS demographic and health surveys l liter DRC Democratic Republic of the Congo LED light-emitting diode EC elemental carbon LNG liquefied natural gas ECOWAS Economic Community of West African States LPG liquefied petroleum gas EnDev Energizing Development Program LSMS Living Standards Measurement Study EPA U.S. Environmental Protection Agency MFI microfinance institution ESMAP Energy Sector Management Assistance MICS Multiple Indicator Cluster Survey Program mil million EU European Union min minute EWSA Energy, Water and Sanitation Authority MJ megajoules FAO Food and Agriculture Organization of the mm million United Nations MMt million metric ton FIP Forest Investment Program mn million fNRB fraction of nonrenewable biomass MT million ton g gram MVP Millennium Villages Project GACC Global Alliance for Clean Cookstoves N2O nitrous oxide GBD global burden of disease NCP National Cookstove Program GDP gross domestic product ND natural draft Gg gigagram (1 billion grams) NGO nongovernmental organization 5 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report NMHC nonmethane hydrocarbon TB tuberculosis OC organic carbon TChar combination TLUD and charcoal stove OECD Organisation for Economic Co-operation TEG thermoelectric generator and Development TLUD top-loading updraft stove PAH polycyclic aromatic hydrocarbon µg/m3 microgram per cubic meter PATS particle and temperature sensor μm micrometer PAYG pay as you go UN United Nations PCIA Partnership for Clean Indoor Air UNACC Uganda National Alliance for Clean PICs products of incomplete combustion Cookstoves PM2.5 particulate matter with diameter of UNDP United Nations Development Programme <2.5 μm UNFCCC United Nations Framework Convention on PoA program of activities Climate Change ProBEC Program for Basic Energy and UNHCR United Nations High Commissioner for Conservation Refugees QA&TS quality assurance and technical support UPDEA Union of African Electricity Producers QA quality assurance USAID United States Agency for International QC quality control Development R&D research and development VAT value-added tax RBF results-based financing VCS verified carbon standard RCT randomized controlled trial VCU verified carbon unit REDD+ Reducing Emissions from Deforestation VER verified emission reduction and Forest Degradation in Developing WACCA West African Clean Cooking Alliance Countries WB World Bank REMA Rwanda Environment Management WHO World Health Organization Authority WLPGA World Liquefied Petroleum Gas SE4All United Nations Sustainable Energy for All Association SME small- and medium-sized enterprise WRI World Resources Institute SSA Sub-Saharan Africa WTP willingness to pay SUM stove-use monitor y-on-y year on year 6 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report © World Bank/Klas Sander 7 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report FOREWORD Evidence from the most recent World Health Organization (WHO) survey on the global burden of disease shows that nearly 600,000 Africans die annually and millions more suffer from chronic illnesses caused by air pollution from inefficient and dangerous traditional cooking fuels and stoves. This tragic and avoidable first-order public health crisis disproportionately harms women and children. Moreover, cooking with wood, charcoal, crop waste, dung, coal, and potentially dangerous and polluting modern fuels, such as kerosene, also imposes tremendous direct costs on economies and households in Sub-Saharan Africa (SSA) and contributes to a wide range of negative environmental and climate change effects. The authors of this report believe that—with the right blend of political will, carefully targeted technical and financial support, and a renewed focus on enabling frameworks—the next 5–10 years can serve as a turning point for the African cooking sector, leading to a much broader uptake of cleaner and more efficient fuels and stoves. Important new developments include the emergence of new, clean cooking solutions; growing demand for fuel-saving alternatives due to escalating pressure on biomass resources and prices; innovation in business models for base-of-the-pyramid (BoP) products; and rising support for the clean cooking agenda from the public health community, governments, and donors. The African cooking sector also increasingly represents an attractive niche market for the private sector—as reflected by increasing entry over the past few years of social enterprises, multinationals, impact investors, and carbon finance projects, including the launch of several large-scale, Africa-based manufacturing facilities for cleaner and more efficient biomass stoves and fuels. However, despite these encouraging trends, there is also ample reason for continued skepticism. So far, three decades of efforts to promote both modern fuels and improved biomass stoves have seen only sporadic success at scale in the region and globally. Penetration of clean cooking solutions remains limited, and efforts to promote their adoption face substantial obstacles, including the limited ability of consumers to afford high- quality clean stoves and fuels, and lack of consumer awareness of, and willingness to pay premium prices for, cooking solutions that offer long-term health benefits. Moreover, large gaps in financial and technical capacity across stove and fuel supply chains, and gaps in the enabling environment for both fuel and stove markets, including the continued absence of coherent quality and performance standards, present additional challenges. Addressing these barriers will require substantially higher private and public investment, greater stakeholder coordination, and improved information to help decision makers learn from past experience, innovate, and measure progress in what continues to be a very opaque and fragmented sector. This overview report, prepared in support of the World Bank’s Africa Clean Cooking Energy Solutions (ACCES) initiative, builds on earlier reports from the World Bank and the Global Alliance for Clean Cookstoves (GACC).1 The report establishes a baseline for the SSA cooking landscape and offers an overview of emerging opportunities to encourage increased investment in clean and improved cooking businesses across the region. This document is meant to serve as a companion to the recently issued report The State of the Global Clean and Improved Cooking Sector (2014), jointly published by Energy Sector Management Assistance Program/World Bank (ESMAP/WB) and the GACC. In terms of its scope, this report covers the full range of “clean” and “improved” cooking solutions in SSA that can enhance the fuel efficiency and emissions performance of traditional technologies, each varying widely in terms of fuel feedstock, design, construction materials, methods of production, and harm mitigation potential (Figure 1).2 The typology in Figure 1 is an attempt to rationalize existing clean and improved cooking-sector definitions and is used throughout the report for consistency. These definitions should be seen only as indicative, given the wide range of cookstove models and performance within each stove category. Wherever possible, the report has linked these definitions to the provisional standards and performance tiers adopted via an International Workshop Agreement (IWA 11:2012) by the International Standards Organization (ISO), which establish a common quantitative vocabulary for clean and improved cookstoves (ICS) based on absolute, not relative or comparative, measures of efficiency, emissions, and safety performance (see Appendix 1).3 The provisional agreement was ratified in June 2013 with the formation of the ISO Technical Committee 285, the key global body charged with developing, approving, and monitoring improved and clean cooking standards in the 8 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Figure 1: Overview of improved and clean cooking solutions “Improved” solutions “Clean” solutions Legacy and Intermediate Advanced ICS Modern fuel Renewable fuel basic ICS ICS Key features Small functional Rocket-style Fan or natural-draft Stoves that rely Derive energy improvements designs with gasifiers with high on fossil fuels from renewable in fuel efficiency focus on highly fuel and combustion or electricity; non-woodfuel over baseline improved fuel efficiency; often have high fuel energy; technologies; efficiency; designed for pellet/ efficiency and often used as typically includes both briquette fuels low emissions supplementary artisanally portable and stoves produced built-in models Technologies • Legacy • Portable rocket • Natural-draft • LPG • Biogas biomass and stoves gasifier (top- • Electric • Ethanol coal chimney • Fixed rocket loading updraft (including • Solar stoves1 chimney (TLUD) or side- induction) • Retained heat • Basic efficient • Highly loading) • Natural gas cookers charcoal improved (low • Fan gasifier/fan jet stoves • Basic efficient CO2) charcoal • Combination • Kerosene wood stoves TLUD and stoves2 charcoal stoves Efficiency Tier 0–2 Tier 2–3 Tier 3–4 Tier 4 Tier 3–4 Emissions3 Tier 0–1 Tier 1–2 Tier 2–3 Tier 3–4 Tier 3–4 Overall Moderate High benefits 1 Legacy stoves categorized as improved within typology but actual performance of many legacy stoves likely falls below provisional ISO/IWA standards 2 Controlled tests of good quality kerosene pressure stoves show low emissions, but field data suggests that many kerosene stoves are actually highly polluting 3 Particulate matter (PM2.5) emissions at point of consumption; research suggests that high rating (Tier 3+) needed for significant health positive impacts coming years.4 The approval of testing methodologies is currently under discussion at the ISO. For the time being, the categorization according to tiers should therefore be understood as provisional. Under the term improved cooking solutions, the report includes all cookstoves that improved fuel efficiency without reducing particulate matter emissions to the low levels necessary for optimal health outcomes as defined by WHO household air pollution guidelines. The “improved stove” category includes (1) basic chimney biomass and coal cookstoves, including many “legacy” biomass cookstoves distributed in early national stove 9 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report programs (ISO Tier 0–2 for fuel efficiency, Tier 0–1 for emissions);5 (2) “basic” portable wood and charcoal ICS (Tier 1–2 for efficiency, Tier 1 for emissions); and (3) highly fuel-efficient “intermediate” rocket-style ICS (Tier 2–3 for efficiency, Tier 1–2 for emissions). Clean cooking solutions include low-particulate-emission technologies (ISO Tier 3–4 for emissions), such as (1) high-performance advanced biomass cookstoves (ACS) which use fans or natural-draft (ND) gasification principles, particularly when such stoves are combined with biomass briquette/pellet fuels;6 (2) modern-energy cooking solutions, including liquefied petroleum gas (LPG), kerosene, natural gas, and electric stoves; and (3) a variety of renewable, nonsolid-fuel solutions, such as biogas, methanol, ethanol, solar cookers, and retained- heat cooking devices. The categorization of kerosene stoves as a clean cooking technology in this report is subject to a major caveat. While well-designed kerosene stoves have minimal particulate emissions, emissions from the low-quality kerosene stoves typically deployed in the SSA region are often much higher than expected and, more generally, there is a growing body of evidence about the dangers of kerosene cooking.7 The report incorporates the review of more than 300 secondary sources; analysis of primary data in dozens of existing market and household surveys, including the recent GACC market assessment reports; publicly available product-testing databases; impact evaluation data from large regional and country programs; focus group discussions with sector stakeholders in eastern, western, and southern Africa regional consultations; and interviews with more than 80 sector participants, including product designers, manufacturers, distributors, financiers, program managers, and policy makers. Data collection efforts have included the development of several country-level databases on historical fuel mix, energy expenditures, fuel prices, and cookstove penetration. Market models and analyses built for the report include an Africa-wide cost-benefit analysis tool for evaluating sector opportunity costs, a fuel use and expenditure forecast model, a cooking consumer segmentation, a manufacturer sales database, and a cookstove market forecast model. Depending on the analysis, the report uses data from 2010–14, with every effort made to ensure comparability across different sources and data points. The resulting figures, facts, and analyses provide the most comprehensive picture of the clean and improved cooking sector in Africa available to date, but also have several weaknesses due to underlying data challenges. Across different sources, sector technology definitions, impact indicators, and sales-tracking methodologies are often inconsistently defined and variably applied. Therefore, end-user data, including information on consumer usage patterns and preferences, are of variable quality and available for only a small proportion of SSA markets. Finally, private-sector ICS and fuel sales information and public-sector cookstove program indicators are self- reported and, therefore, not always credible. The information assembled in this report constitutes a best-effort attempt to harmonize definitions and data sources, with the caveat of occasional lack of precision due to definitional and data-quality challenges. The report interprets data conservatively and highlights potentially contentious and ambiguous areas where appropriate. Consequently, this document should be seen as a starting point for sector analysis, and the data should be updated in future editions as the African cooking sector evolves. 10 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report © World Bank/Klas Sander 11 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Executive Summary Reliance on solid-fuel cooking in Sub-Saharan Africa (SSA) is a large and growing problem. More than 700 million Africans (82%) use solid fuels, such as wood, charcoal, dung, crop waste, and coal, for their primary cooking needs—a number that will reach 850–900 million by the end of the decade. This high level of solid-fuel use, combined with household reliance on inefficient and unsafe traditional cookstoves, constitutes a first-order public health crisis: household air pollution (HAP) from solid-fuel cooking emissions kills nearly 600,000 Africans annually and is now recognized as the second-largest health risk factor in terms of death and disability in the region. Solid-fuel cooking in SSA accounts for up to 1% of global greenhouse gas emissions and 6% of global black carbon, an important additional driver of climate change because it both absorbs solar radiation in the atmosphere and deposits soot on snow and ice surfaces. Solid-fuel cooking also imposes significant costs on African households and economies, with a mid-range estimated opportunity cost of 3% of regional annual gross domestic product (GDP)—including avoidable spending on solid fuels, time losses due to firewood collection, the economic costs of increased mortality and morbidity burdens, and the environmental and climate costs of deforestation and carbon dioxide emissions. The clean and improved cooking sector in SSA has evolved significantly, but is still highly underdeveloped. Only 11% of Africans use “clean” cookstoves that run on modern fuels, such as liquefied petroleum gas (LPG) (5%) and electric stoves (6%), as their primary cooking appliances. Many of these households continue to use traditional biomass-burning stoves as their secondary cooking device due to the common phenomenon of fuel and stove “stacking” (simultaneous usage of multiple fuels and stove technologies). Kerosene, which is used by 7% of Africans, likely does not qualify as a clean cooking solution in many instances, given the increasing evidence of harm from typical kerosene stoves in Africa. Stoves that run on such renewable fuels as biogas, ethanol, and solar are uncommon (less than 1%), and the penetration of “advanced” biomass gasifier cookstoves (less than 0.1%) that can come near the International Organization for Standardization’s (ISO’s) Tier 4 emission performance is still at a pilot stage. A growing number of SSA households (about 3.5%) use intermediate improved cookstoves (ICS) (e.g., rocket stoves), which are substantially more fuel efficient but do not achieve the emission reductions needed to realize the full health and environmental benefits of clean cooking. Another 9–10% of SSA households have access to both basic ICS (less than 5%) and legacy cookstoves (less than 5%) that offer only moderate improvements in fuel efficiency and emissions over traditional cooking technologies. In aggregate, Africa has a significantly lower rate of access to clean and improved solutions (25%, excluding legacy stoves) than any other region globally. The continuation of current trends over the next decade is likely to offer ample opportunities for transformative advances in the adoption of more efficient and cleaner cooking solutions. On the demand side, key factors include a large urban population (a result of the region’s two decades of rapid urban population growth); the emergence of an aspirational lower/middle class with rising incomes (the African population with discretionary income is expected to grow 50% over the next decade, to 130 million households); and escalating prices for cooking fuel (charcoal prices rose 11%, and liquefied petroleum gas (LPG) prices rose 8%, annually in 2000–10), a consistent long-term trend despite recent fossil fuel price declines in 2014-2015. A large and growing share of SSA consumers (50%) already pay something for their cooking fuels and can benefit tangibly from adopting even basic energy-saving cookstove alternatives. There is growing evidence across multiple SSA markets of consumer willingness to pay for basic ICS. Evidence of consumer demand for more expensive intermediate and advanced ICS is more limited, but emerging consumer survey data suggest that—with extensive consumer awareness building and the right products—demand for higher-cost, quality-controlled cooking solutions could grow rapidly. On the supply side, key trends include accelerating technological innovation across the full spectrum of cooking technologies, including most notably the development of fan-gasifier biomass cookstoves that combine high rates of fuel efficiency (up to 50%) and very low levels of particulate-matter emissions (90%+ reduction vis-à- vis traditional biomass stoves). Other notable developments are the increased use of scalable and centralized industrial production—international players, such as Philips [ACE], Envirofit, and BURN Manufacturing, have opened new Africa-based manufacturing facilities, and EcoZoom also plans to do so in the near future—along with improved capacity for regional semi-industrial players. All these factors hold the promise of improved 12 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report performance and higher product quality at lower cost. Another important supply-side trend includes the increasing availability of financing for manufacturers and distributors through the Global Alliance for Clean Cookstoves (GACC), the World Bank, the United States Agency for International Development, the Global Villages Energy Partnership, and recently launched private funds, such as the Base of the Pyramid Impact eXchange Fund, or BIX. Meanwhile, two important trends are affecting both supply and demand in the region. First is the emergence of new distribution and financing models for reaching the poor, including carbon finance, microlending, lay-away and leasing schemes, and utility models for distributing renewable biomass pellet or ethanol fuels. Second is the growing number of entrepreneurs across all segments of the clean fuel and ICS value chain: over the past five years, the number of Africa-based industrial and semi-industrial ICS manufacturers has grown from less than 10 firms to more than 40. The enabling environment for clean cooking solutions uptake is also seeing positive developments. There is a growing consensus among regional policy makers on the case for clean cooking energy. National cookstove programs are being launched or aggressively scaled up in such countries as Ethiopia, Ghana, Malawi, Nigeria, Rwanda, Senegal, and Uganda. There is an increased focus on cookstove quality testing and standards, as manifested by the adoption of provisional International Organization for Standardization/International Workshop Agreement (ISO/IWA) standards for stoves (see Appendix 2) and the growing number of testing centers across the region with increasing capacity to carry out tests according to the established protocols. There is rising interest from donors, nongovernmental organizations (NGOs),, and industry in championing innovation in clean and renewable cooking technologies. The monitoring and evaluation of cooking projects is improving. And, last but not least, global coordinating platforms are emerging—such as the GACC and the United Nations’ Sustainable Energy for All; regional market transformation efforts, such as the World Bank’s Africa Clean Cooking Energy Solutions program; and fuel-specific initiatives focused on Africa, such as the Global LPG Partnership and the Africa Biogas Partnership Programme. Major obstacles remain on the path to maximizing the reach of clean and improved cooking solutions in Africa. Consumers’ limited willingness to fully adopt new cooking solutions and limited ability to pay for higher- cost, clean, and improved cookstoves and fuels are the greatest long-term obstacles to broader adoption of clean cooking in Africa. From the standpoint of willingness to adopt, limited consumer exposure to new technologies and low awareness of their benefits limit demand. Even when consumers are educated about stove benefits, however, willingness to adopt is often still low, due to the new solutions’ inability to fit with consumers’ cooking preferences (due to the reality or perception of inappropriate design); lack of consumer trust in stove performance and durability; concerns about the accessibility of fuel supply and after-sales support; and the behavioral (e.g., risk aversion, present bias) and cultural obstacles to sustained adoption of new technologies. The willingness-to- adopt challenge is not just an obstacle to initial stove uptake, but also affects sustained adoption and use—as manifested in the near-universal phenomenon of stove and fuel “stacking,” where end users retain traditional cooking solutions for use alongside clean or improved solutions to accommodate both diverse household cooking needs and the force of tradition. Even where households are willing to adopt improved and clean cookstoves and fuels, they often lack the ability to pay for the stove and fuel due to insufficient disposable incomes and/or the lack of savings. This “affordability challenge” is particularly acute for clean cooking solutions. The high upfront costs of higher-end cooking appliances (US$75–100 for fan gasifiers and US$25–100 for LPG and electric modern-fuel stoves) and the high ongoing costs of modern-fuel use relative to traditional biomass alternatives serve as a major constraint to the size of the clean cooking market. Affordability is likewise consistently rated as the top demand constraint by the manufacturers and distributors of industrially manufactured, high-quality intermediate ICS (rocket wood and charcoal stoves) in the US$15–50 range. For low-cost improved stoves (i.e., basic ICS in the US$3–15 range), aside from the poorest segments of the African population, affordability is a smaller obstacle, but nonetheless still serves as a brake on faster market development. In making the decision to adopt or pay for improved and clean cooking solutions, Africans are primarily interested in fuel and time savings, convenience, smoke reduction, durability, and safety, with relatively little interest in the long-term health benefits and public-good aspects of cooking solutions. Reduction of fuel expenditures is the most powerful motivator among these factors, but does not apply for many end users. Only half of SSA 13 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report households currently purchase cooking fuel, and many such fuel-buying households continue to rely on fuel collection in parallel, adjusting their mix of purchased and collected firewood as opportunities and economic situations dictate. Although the number of such fuel-purchasing households is growing, the pace of this change is unclear due to a lack of long-term data. The economic motivation for fuel-saving stoves is particularly weak for the poor (i.e., those earning less than $1.25 per day), collectors of wood and other biomass fuels (such as dung and crop waste), who constitute nearly 30% of the SSA population. Biomass-collecting households do face the physical harms and time burdens of firewood gathering, but tend to place a low value on time losses, given the low opportunity cost of rural labor; polychronic traditional cultures that generally undervalue time; and patriarchal family structures in which men play the dominant role in stove-purchasing decisions, leaving the time burdens of fuel collection to fall primarily on women and girls. Many of these willingness-to-adopt and -pay issues can be addressed via consumer education and awareness building, as well as marketing solutions that enhance end-user trust (e.g., warranties, right to return). In addition— assuming that the underlying technologies are appropriately designed, distribution and financing approaches can build up end-user comfort through exposure (e.g., free trials), and innovative financing techniques (e.g., installment payment plans, pay-as-you-go/utility business models, and consumer financing) can address the liquidity constraints of those consumers whose income levels can sustain stove purchases but who lack the near-term savings needed for stove purchases. For many cooking solutions, even when such approaches are applied, willingness to pay will remain a barrier to adoption. There is strong evidence that most African consumers are not willing to pay price premiums for stoves and fuels that generate incremental long-term health benefits—a factor that inherently limits the market-based potential of clean solutions that cannot compete with traditional or improved stoves on purely economic terms. Willingness to pay is also an issue for intermediate ICS technologies, where actual willingness to pay can be significantly below the stove’s fair market price. Even after willingness to pay is improved through marketing, many ICS providers will still need to subsidize the upfront cost of their stoves—with carbon revenues, for example—to see adoption at scale, particularly in rural areas. On the supply side, corresponding obstacles to wider adoption of improved and clean cooking solutions include the cost and complexity of last-mile distribution; the limited business management capacity and financial constraints of cooking-sector entrepreneurs; the still-limited adoption of uniform quality standards and product certification to minimize market spoilage; biomass supply market failures limiting fuel sustainability; and regulatory constraints, such as high taxes and duties on clean technologies or perverse subsidy incentives for the ongoing use of harmful fuels. To address these various obstacles, sector funding is a cross-cutting challenge involving financing for fuel- supply chains, working capital for improved stove producers and distributors, public-sector funding for market transformation programs and enabling market infrastructure, and—where sensible—targeted subsidies and incentives tied to access, health, and climate change goals. The International Energy Agency (IEA) estimates the funding needed for universal access to clean cooking energy in SSA at more than US$1 billion annually through 2030—whereas the current fund flow is US$50–125 million. Public- and donor-sector funding, in particular, is far below levels that can realistically address the immensity of the health challenges caused by household air pollution: current SSA funding levels are an estimated US$100–250 per death for HAP versus US$2,000–4,000 per death for public health crises, such as HIV/AIDS and malaria. The “business-as-usual” scenario for the clean and improved cooking sector’s growth is encouraging but falls far short of potential and need. Existing market dynamics will ensure that tens of millions of new SSA households will gain access to at least minimally improved cooking solutions by the end of the decade without any further interventions. But by 2020, the business-as-usual scenario would still leave 80% of Africa’s population without clean cooking solutions and more than 60% without access to even minimally improved cooking solutions. This would still represent a much lower level of access than what is currently seen in such regions as South Asia, where the lack of clean cooking solutions is being addressed as a major crisis. Furthermore, in the absence of significant public- and private-sector investment, the spread of clean cooking solutions across SSA will be highly uneven—with successes in countries, such as Ghana, Kenya, Senegal, and South Africa (where the combined penetration of ICS and clean fuels is already above 50%) serving as exceptions amidst the overwhelming majority of SSA countries still mired in traditional solid-fuel cooking. In places where ICS adoption is growing quickly, much of this growth is still in basic and intermediate ICS, rather than in clean 14 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report cookstoves and fuels. Furthermore, the vast gap in clean cooking access between rural and urban areas is likely to widen further in the absence of new targeted investments. African governments, the development community, and the private sector can and must do better. Disrupting the status quo will require stepped-up investment and a differentiated approach. While this is a moment of great promise, it is also one of great responsibility for sector stakeholders. To ensure that the current revival of interest in clean cooking does not become a passing fad or disappoint with meager results, new investments are needed to accelerate the uptake of clean, high-quality cooking appliances and fuels in such countries as Cameroon, Côte d’Ivoire, Ghana, Kenya, Nigeria, Senegal, and South Africa, where sizable markets for clean fuels already exist. Many of these countries—and others, such as Ethiopia and Uganda—already have significant markets for basic and intermediate ICS that could likewise benefit from further acceleration. At the same time, it is also vital to establish the foundations for clean and improved stove ecosystems in the vast majority of other African countries, where the current penetration of ICS is negligible and the enabling environment antecedents for clean cooking are weak. While a major push is needed in both cases, the relative intervention priorities and appropriate technologies will vary by market stage. In less developed countries, public-sector support will be particularly critical, since the creation of artisanal ICS markets and early-stage “market-seeding” awareness campaigns are time- and resource-intensive efforts in which the private sector is typically less willing to invest. Changing the status quo likewise requires a significant further tailoring of sector approaches based on target technologies, consumer-segment characteristics, and policy objectives. Market-led approaches hold significant promise for expanding access to clean cooking solutions for middle-income consumers, particularly for the urban and peri-urban segments that have growing disposable incomes. The optimal strategy for such consumers involves expanding uptake of modern fuels and, where biomass cooking persists, progressively displacing household biomass stoves with clean or highly improved biomass cooking solutions to transition the entire fuel “stack” to cleaner cooking energy. Poor urban consumers, who already often face significant fuel costs, similarly offer growing opportunities for the private sector. Reaching them, however, will likely require different strategies and challenges, such as (1) capitalizing on carbon finance markets and growing demand via businesses that generate fuel savings (e.g., via highly efficient charcoal stoves), or (2) offering competitively priced alternatives to expensive biomass (LPG, biofuels, biomass briquettes) that can also create significant health co-benefits. In contrast, for rural poor consumers and other marginalized segments (e.g., refugee camp populations), the path forward will very likely involve continuing to expand low-cost artisanal ICS markets that, while potentially generating significant fuel savings, will realistically have only minimal health benefits. High-quality intermediate ICS, advanced biomass cookstove (ACS) technologies, and clean fuels will likely remain inaccessible to most rural African consumers without public-sector leadership and significant subsidies for many years to come. Recommendations Aside from an across-the-board need for new investments, the report highlights the following specific recommendations for sector stakeholders. Public Sector, Donors, and NGOs • Increase investment in clean cooking solutions, while maintaining momentum for intermediate and basic ICS technologies where cleaner solutions are not feasible in the near term. The scale of the HAP public health crisis calls for a revision of donor priorities, with a need for expanded investment in clean cooking technologies. Achieving proportionality to investments in such public health challenges as HIV/ AIDS and tuberculosis would require at least a tenfold increase in public-sector and donor funding for clean cooking technologies. At the same time, the slow pace of transition to clean solutions and the unaffordability of these solutions for the rural poor dictate sustained large investment in intermediate and basic biomass ICS. • Design interventions to drive consumer behavior change; simply distributing cleaner cooking solutions and fuels will not lead to optimal health and environment outcomes. The challenge of achieving the benefits of universal clean cooking in SSA is not simply one of technology and economics. Like water 15 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report and sanitation programs and other public health initiatives, clean cooking promotion efforts can achieve health impact objectives only when accompanied by large-scale behavior change in the target end-user population. • Prioritize market-based approaches, but also deploy direct subsidies linked to health and climate impacts. Market-led models should be emphasized wherever feasible to ensure sustainability. However, maximizing climate and health benefits might also require targeted subsidies delivered through carbon markets and focused “pull” mechanisms (e.g., results-based credits for health benefits). • Support sustainable production of clean-biomass and renewable-fuel alternatives alongside stove efficiency and emissions. Given rapidly rising demand, more efficient cooking solutions alone will not be enough if the sustainability issues in African woodfuel value chains remain unaddressed. • Focus on providing critical public goods to accelerate the development of the clean cooking sector. Emphasize consumer education, access to finance, funding for research and development (R&D), the expansion of standards and testing, and clean cooking focused policies (e.g., tax, tariff, and subsidy reform). Private Sector • Invest to capture the opportunity. Despite many challenges, the untapped SSA demand for clean and improved cookstoves is immense. The opportunity is further enhanced by a resilient and fast-growing voluntary carbon finance market and the potential for additional funding streams from social impact investors, governments, and donors for the health benefits of clean cookstoves and fuels. • Focus on cooking-fuel opportunities, not just cookstoves. The SSA cooking-fuel market (US$20 billion) is orders of magnitude larger than the market for cooking appliances, though it is also more complex due to often perverse regulatory incentives, vested interests, significant investment requirements in the case of modern fuels, and fragmented and informal markets for biomass. • Address the affordability challenge to grow market share. Recommended measures include reducing stove prices via low-cost design and economies of scale, transitioning to local production or assembly, and embracing innovative distribution and financing models that can lower upfront stove costs. • Address willingness-to-pay (WTP) barriers head on. Even if you have the ideal product, focus on adapting marketing, distribution, and financing models to address WTP challenges, such as low consumer awareness, trust gaps, and liquidity constraints through proven approaches, including consumer education, field demonstrations, trial periods, warranties, and pay-as-you-go schemes. • Use a variety of distribution channels, with an emphasis on getting closer to the consumer. Getting to scale requires exploiting a range of models (e.g., direct, third-party, institutional), with the greatest scale seen by those who take on the expense of building direct bridges to consumers, or partner with third parties with direct-sales or demand-aggregator capabilities (e.g., distributors of synergetic products and household appliances, carbon project coordinating/managing entities). • Design products with an emphasis on the complete end-user experience and attention to quality at every provisional ISO/IWA performance tier. Most consumers, even the poor, are willing to pay for improved design, with an emphasis on “aspirational” stove designs that require minimal behavior change, while maximizing fuel savings, end-user convenience (e.g., cooking time), and durability. 16 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Key Facts and Figures The Cooking Energy Challenge in Sub-Saharan Africa • Cooking with traditional fuels and stoves represents a US$32 billion opportunity cost (3% of SSA GDP). • Each year there are nearly 600,000 avoidable African deaths, and more than 26 million disability- adjusted life years are lost. • More than 40 million worker years are wasted each year on fuelwood gathering and slow biomass cooking. • Solid-fuel cooking in SSA accounts for 6% of global black carbon emissions and 1.2% of carbon dioxide emissions. Cooking-Sector Demand • An estimated 700 million Africans (82%) cook primarily with solid fuels (and 850–900 million will do so by 2020), 7% with kerosene, 5% with LPG, and 6% with electricity. • SSA is already a large cooking market: US$20 billion was spent annually on cooking fuels in 2010, and US$300–400 million was spent on all types of stoves. By 2020, fuel spending is set to more than double to US$47 billion. • Fuel prices are rising fast across the region, stimulating demand for fuel-saving solutions. Annual price growth is 8% for LPG and 11% for charcoal, and the average charcoal cooking cost is now higher than that for LPG, a trend that has accelerated with recent fossil fuel price declines. • Half of all SSA consumers already regularly pay for cooking fuels. Although 70–80% can afford the upfront cost of basic ICS (US$5), less than 20% can easily afford high-end cookstoves (US$50–100). • Willingness to pay/adopt is a major constraint: 10–30% of SSA consumers are not readily willing to adopt new solutions. The initial willingness to pay for quality ICS is often 20–50% of stove value, but can be increased with marketing and consumer education. Cooking-Sector Supply • In SSA, the growth in uptake of clean modern-fuel solutions is slow—the annual growth of primary users is 3.5% for electric stoves and less than 5% for LPG—though total volumes of fuel use are likely growing faster. • The biomass ACS market is nascent: 50,000–100,000 gasifier stoves have been distributed across a handful of SSA pilots. • The number of renewable fuel project pilots is growing, but penetration is likewise very low: about 40,000 biogas stoves, 50,000 solar cookers, 75,000 ethanol stoves, 0.5 million retained-heat cookers, and 25,000 biomass pellet stoves. • Biomass ICS distribution is small but growing: fewer than 10 million SSA households use basic ICS, 5–7 million use intermediate “rocket” or highly improved charcoal ICS, and another 7–8 million have legacy stoves. • The ICS supply is focused on urban areas: less than 20% of urban solid-fuel households have ICS, versus less than 5% of rural households. • More than 90% of ICS in Africa are artisanally manufactured cookstoves—chiefly portable, ceramic, jiko-style ICS; legacy chimney stoves; and, in select geographies, efficient rocket stoves. • Adoption of industrially manufactured ICS is growing quickly: there are more than 40 SSA industrial/ semi-industrial manufacturers (35 more than five years ago), and major players are seeing 35–100% annual growth in sales and 5–25% self-reported margins (10% on average), including carbon revenue streams. • Sector financing is a major challenge: funding needs (US$1 billion annually) are 8–20 times the current level of investments by donors and the private sector in ICS (US$50–125 million annually). 17 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report © BioLite/2014 The Case for Clean Cooking chapter 1 The Case for Clean Cooking This chapter draws on cutting-edge academic research and a wealth of recent household survey data to build the case for donor, government, and private-sector investment in improved and clean cooking solutions in Africa. The analysis begins by examining the harmful effects of traditional cookstoves and fuels. This includes (1) an assessment of the economic opportunity cost of traditional cooking for the region and (2) an aggregation of never previously linked research on the economic, social, health, and environmental harms resulting from Africa’s dependence on solid fuels. We then review the potential of existing clean and improved stove technologies to mitigate these harmful effects in SSA. The Harmful Effects of Solid-Fuel Cooking and Traditional Cookstoves Reliance on solid fuels and inefficient cookstoves imposes significant costs on SSA. More than 700 million Africans (82%) depend primarily on solid fuels for their cooking needs, and the penetration of clean cooking technologies in this population is negligible (<0.1%).8 The mid-range economic value of the resulting health, economic, environmental, and gender-equity externalities is a staggering US$40 billion annually (US$5–58 billion) or 3% of the region’s annual gross domestic product (GDP). 9 This chapter addresses each area in turn. Health The release of particulate matter, carbon monoxide, and other harmful products of incomplete combustion (PIC) from solid-fuel cooking is strongly linked to acute lower respiratory infections (ALRI), chronic obstructive pulmonary disease (COPD), lung cancer, ischemic heart disease, cerebrovascular diseases, cataracts, and low birth weights.10 Across these illnesses, household air pollution (HAP) contributes to at least 581,000 premature African deaths per year and the loss of more than 26 million disability-adjusted life years (DALYs), out of a global total of 4.3 million deaths (2012) and 110 million HAP DALYs (2010).11 In SSA, HAP was the second-highest risk factor for DALYs and the third-highest driver of premature deaths in 2010—a ranking likely to increase in the next revision of the Global Burden of Disease database (Figure 2). In absolute terms, the level of HAP-related mortality in Africa already exceeds SSA public health crises, such as tuberculosis (TB); globally, HAP deaths exceed the mortality burden from HIV/AIDS, TB, and malaria combined.12 Other health effects of solid-fuel cooking not quantified in this total, with varying degrees of epidemiological evidence, include asthma, TB, adverse pregnancy outcomes, pediatric sleep disorders, depression, bacterial meningitis, a variety of moderate-to-severe physical injuries associated with firewood collection, burns, and widespread minor ailments from smoke inhalation, such as eye irritation and headaches.13 The negative health effects of cooking with low-quality kerosene cookstoves in Africa are likewise not included in current disease estimates, but could be substantial.14 20 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Figure 2: Sub-Saharan Africa mortality and morbidity, by risk factor (2010) Disability-adjusted life years (millions) Avoidable deaths (thousands) Disability-adjusted life years (millions) Avoidable deaths (thousands) Childhood underweight 44 High blood pressure 504 Childhood underweight 44 High blood pressure 504 HAP 12 Childhood underweight 499 HAP 12 Childhood underweight 499 Suboptimal feeding 6 HAP 464 Suboptimal feeding 6 HAP 464 Alcohol use 14 Alcohol use 348 Alcohol use 14 Alcohol use 348 Iron deficiency 13 Suboptimal breastfeeding 241 Iron deficiency 13 Suboptimal breastfeeding 241 High blood pressure 12 Diabetes 232 High blood pressure 12 Diabetes 232 Tobacco exposure 8 Low-fruit diet 192 Tobacco exposure 8 Low-fruit diet 192 Poor sanitation 7 Tobacco exposure 176 Poor sanitation 7 Tobacco exposure 176 Vitamin A deficiency 7 High Body Mass Index 144 Vitamin A deficiency 7 High Body Mass Index 144 Diabetes 6 Low physical activity 127 Diabetes 6 Low physical activity 127 Note: As of the latest World Health Organization/Global Burden of Disease (WHO/GBD) analysis using 2012 data, the estimated number of HAP deaths in SSA stands at 581,000, suggesting that HAP may become the leading regional risk factor for mortality once the GBD data is fully revised for 2013-14. Note: As of the latest World Health Organization/Global Burden of Disease (WHO/GBD) analysis using 2012 data, the estimated number of HAP deaths in Sources: 2010 SSA stands Global Burden at 581,000, of Disease suggesting (available that HAP at http://www.healthmetricsandevaluation.org); may become Dalberg the leading regional risk factor for mortality analysis. once the GBD data is fully revised for 2013-14. Sources: 2010 Global Burden of Disease (available at http://www.healthmetricsandevaluation.org); Dalberg analysis. Figure 3: Relative incidence of HAP-related morbidity across Sub-Saharan Africa (2010) HAP DALYs per 1,000 people 110 79 71 61 63 56 59 52 54 46 47 48 43 37 39 40 40 35 36 36 33 27 29 24 16 Botswana Senegal Uganda Ghana Mozambique Nigeria Tanzania Sierra Leone Madagascar Benin Cameroon Kenya Zambia Mali Liberia Côte d’Ivoire DRC Malawi South Africa Zimbabwe Guinea Rwanda Ethiopia Burkina Faso Chad Sources: 2010 Global Burden of Disease (available at http://www.healthmetricsandevaluation.org/); Dalberg analysis. 21 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Aside from differences in fuel preferences, cooking technologies, and general health outcomes, the wide disparities in HAP-related morbidity also stem from differences in household cooking behavior. For instance, the proportion of households cooking outdoors—typically presuming that better stove ventilation results in lower exposure to particulate emissions—is highly culture-dependent, with major differences across SSA (Figure 4). These differences suggest that the importance of public efforts to improve access to clean and improved cooking solutions, relative to other drivers, such as economic and climate change impacts, will vary significantly by country. Figure 4: Share of households cooking outdoors—select SSA countries 58% 57% 46% 41% 41% 38% 32% 25% 24% 20% 17% 16% 14% 14% 12% 9% Sierra Leone Liberia Kenya Lesotho Zambia Ghana Malawi Uganda Nigeria Rwanda Madagascar Swaziland Zimbabwe Togo Senegal Sources: DHS/MICS surveys 2000 2013; Dalberg analysis. Ethiopia Economics African households dedicate a significant portion of their expenditures (7% on average) to lighting and cooking energy (Figure 5). The largest economic impact falls on the urban poor, who spend 15–20% of their monthly incomes on high-cost cooking fuels, such as charcoal, in some urban slum areas.15 Because of the inefficiency of existing cookstoves and fuels, total fuel spending has risen to US$10 billion annually, or half of the total African household cooking fuel bill of US$20 billion—an amount that will more than double in the coming decade if current price and fuel-consumption trends continue.16 Africans also waste billions of potentially productive hours on avoidable fuel-collection tasks and—due to the slow cooking time of traditional solid-fuel cookstoves—suffer an efficiency loss of roughly 40 million potentially productive person years annually.17 For an individual African firewood-gathering household, the average time spent on fuel collection daily ranges from just under 1 hour to more than 5 hours, with a regional average of 2 hours spent on the task daily (Figure 6)—an immense loss of human productivity. 22 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Figure 5: Cooking and lighting energy as a share of household expenditure Modern fuels Solid fuels 11 Total2 10.5 10 9,1 6.9 6.6 6.3 6.1 7.0 6.0 ~7% 10.4 5.6 5.5 1.9 5.2 3.6 4.7 4.7 4.7 4.4 3.1 3.0 2.6 2.5 3.8 1.7 3.4 2.4 4.4 3.0 1 3.0 1 3.0 1 3.0 1 3.0 1 3.0 1 3.0 1 1.3 1.4 0.7 Angola Djibouti Malawi Ethiopia Burkina Faso Ghana Uganda Madagascar Senegal Cameroon Cote D’Ivoire Gabon Zambia Sierra Leone South Africa Nigeria Kenya 1. Solid fuel share estimated at 3.2% based on country average (Daurella and Foster 2009) wherever only modern fuel data are reported. 2. Modern-/solid-fuel split not available. Sources: World Bank country surveys in Bacon et al. (2010); national consumption surveys; World Bank Survey-Based Harmonized Indicators Program (SHIP); Dalberg analysis. Figure 6: Time spent on firewood collection in Africa Hours per household Hours per household 5.0 5.0 4.0 4.0 3.5 3.5 3.1 3.1 2.7 2.7 2.6 2.6 2.3 2.3 2.2 2.2 2.1 ~2.1 2.1 1.9 1.8 ~2.1 1.9 1.8 1.7 1.7 1.7 1.7 1.7 1.7 1.7 1.7 1.7 1.7 1.6 1.6 1.6 1.6 1.5 1.5 1.0 0.9 0.8 1.0 0.9 0.8 Leone Cameroon Niger Senegal Benin Liberia Ethiopia Madagascar Uganda Malawi Kenya Zimbabwe Faso Botswana Africa Rwanda Sudan Zambia Nigeria Ghana Namibia Tanzania Leone Cameroon Niger Senegal Benin Liberia Ethiopia Madagascar Uganda Faso Botswana Africa Rwanda Sudan Zambia Malawi Kenya Zimbabwe Nigeria Ghana Namibia Tanzania Burkina South Burkina Sierra South Sierra Sources: Database of 51 data points (1998 2012) for 21 SSA countries from census data; household (HH) surveys; Gesellschaft für Internationale Zusammenarbeit (GIZ); Sources: Energy Database Sector of 51 data Management points (1998 Assistance 2012) Program for 21 SSA (ESMAP); countries Dalberg from census data; household (HH) surveys; Gesellschaft für Internationale Zusammenarbeit (GIZ); analysis. Energy Sector Management Assistance Program (ESMAP); Dalberg analysis. 23 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Environment and Climate Change The production and use of solid fuels for cooking lead to the consumption of more than 300 million tons (MT) of wood annually across SSA.18 Of this amount, the wood harvested for charcoal production (130–180 MT annually) contributes to forest degradation, biodiversity loss, and, in a few instances, localized deforestation.19 In terms of climate change, SSA solid-fuel use and charcoal-fuel production generate 120–380 MT of carbon dioxide (CO2)-equivalent of Kyoto protocol greenhouse gases (GHGs) (0.4–1.2% of global CO2 emissions) and up to 600 MT CO2-equivalent, including non-Kyoto PIC (Figure 7).20 Figure 7: Contribution of solid-fuel cooking to GHG and black carbon emissions in SSA Emissions share of total (%) 0.41.2%1 4% 6% SSA solid-fuel cooking Residential solid-fuel 19% use in other regions All other sources globally 95% 75% GHG (Kyoto) Black Carbon 1. Assumes a fraction of nonrenewable biomass (fNRB) range of 10 90% for rewood and 50 90% for charcoal, based on estimates from UN Framework Convention on Climate Change (UNFCCC) and Intergovernmental Panel on Climate Change (IPCC). Sources: Bottom-up emissions inventory for CO2 and BC based on known fuel-use volumes and typical SSA stove emissions pro les; total BC from residential solid-fuel use estimates from U.S. Environmental Protection Agency (EPA 2011) and Bond (2013); Dalberg analysis. Solid-fuel cooking in SSA also accounts for 6% of global black carbon (BC) emissions. The impact of BC emissions—the granular form of pure carbon that is the primary component of soot—is an important area of research because BC emissions contribute to local climate change and may be an important anthropogenic driver of global warming.21 Aside from issues associated with solid-fuel consumption, there are (1) inefficient biomass fuel production technologies, such as low-efficiency charcoal kilns, and (2) governance challenges across traditional biomass supply chains—including lack of sustainable forestry management, high rates of informality, poorly targeted taxes, and supply bans—that hinder the sustainability of traditional cooking approaches.22 These challenges must be addressed as part of any holistic clean cooking interventions. The scale and severity of the environmental impacts of traditional biomass cooking are likely to vary greatly across SSA. Likewise, climate-forcing emissions from traditional solid-fuel cooking are not spread evenly. Five large countries account for half of the solid-fuel-linked emissions in the region, and the top-10 SSA countries account for two-thirds of the emission-related impacts.23 Figure 8 shows one potential way of visualizing the relative environmental threat potential across SSA. The intensity of woodfuel harvesting is shown on the vertical axis, and existing deforestation pressures appear on the horizontal axis. The bubble size reflects a country’s total woodfuel (charcoal and firewood) consumption from biomass cooking. The total solid-fuel population size is highly correlated with the GHG and BC emission potential of each country, and also shows the relative scale of the deforestation and degradation challenge across geographies. 24 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Figure 8: Biomass pressure map: solid-fuel cooking in Sub-Saharan Africa 11.0 Annual woodfuel consumption as share of total biomass Moderate Burundi 9.0 Niger Mauritania Lesotho High 8.5 8.0 7.5 Uganda 7.0 Ethiopia 6.5 6.0 Rwanda Sierra Leone Nigeria 5.5 5.0 Low Sudan Kenya Malawi Ghana 2.0 Mali Madagascar Burkina Benin 1.5 Faso Somalia Zambia Senegal 1.0 Chad 0.5 Côte d’Ivoire Zimbabwe Tanzania 0.0 DRC Liberia Cameroon South Africa Mozambique South Sudan -8.6 -8.4 -0.6 -0.4 -0.2 0.0 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 2.2 2.4 2.6 3.6 Deforestation (% annual increase, 20002010) Note: Bubble size re ects size of 2010 solid fuel population; biomass de ned as above-ground biomass; woodfuel includes charcoal and rewood. Sources: Food and Agriculture Organization of the United Nations (FAO) deforestation data; Dalberg global cooking fuel use database drawing on WHO, demographic and health surveys (DHS), Multiple Indicator Cluster Survey (MICS), and Living Standards Measurement Survey (LSMS) data; Dalberg analysis. The figure shows clearly that a number of Africa’s largest countries—such as Ethiopia, Ghana, Nigeria, and Uganda, as well as several smaller Sahelian nations—fall into the highest woodfuel biomass pressure zone. In this zone, high rates of deforestation are accompanied by significant use of woodfuel for cooking. While the two variables may not be directly related, it is reasonable to presume that the risks of woodfuel scarcity are higher in those geographies where the two trends coincide. There is also a wide intermediate zone of countries where the likelihood of forest degradation effects is significant, especially for those countries using a significant portion of their national stocks for cooking. For a number of countries in the “low-pressure” zone, biomass scarcity and forest degradation may still be significant issues at the subnational level, even if the effect is not visible in the aggregate. Furthermore, recent research suggests that, in countries like Rwanda, the official Food and Agriculture Organization of the United Nations (FAO) forest cover data used in this analysis may significantly understate actual deforestation rates.24 Gender Equity The negative effects of traditional solid-fuel cooking on gender equity are clear (Figure 9). Women bear a disproportionate burden of the costs of solid-fuel cooking because of their primary responsibility for fuel collection (in most markets), cooking duties, and greater risks of physical injury and sexual violence during fuel- collection trips.25 25 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Figure 9: Firewood collection and cooking time, by gender Firewood collection (minutes per day)1 Cooking time (hours per day) Women Men Guinea 20 2.35 3 Burkina Faso 0.10 Malawi 19 3 Tanzania 2.41 16 0.28 Benin 4 Guinea 1.31 Tanzania 9 0.04 5 Burkina Faso 6 3.73 Lesotho 2 1.48 South Africa 6 3 1.34 Malawi 0.20 Ghana 37 30 3.21 Rwanda Madagascar 7 0.08 12 Ethiopia 4.57 Ethiopia 7 100 (Tigray) 0.29 (Tigray) 1. Average across all households in the given country; collection times for rural rewood collectors only are much higher. Sources: World Bank/Indepencent Evaluation Group (IEG) (2006); Blackden & Wodon (2006); Cecelski (2000); FAO (2011); Lawson (2007); Tanzania TUS (2006); Huba & Paul (2007); Kiros (2011); Dalberg analysis. Notably, despite women’s greater proximity to cooking fires, new epidemiological evidence suggests that in absolute terms, men and boys bear a slightly higher burden of HAP-related disease because of the generally higher background mortality and morbidity rates in the male population.26 In addition, roughly half of the solid-fuel HAP disease burden falls on children under the age of five.27 Other negative social outcomes include decreased educational opportunities for children, particularly girls; impaired nutrition resulting from the diversion of scarce resources to fuel purchases; and the aesthetic disutility of kitchens, dishes, and home environments damaged by smoke and soot.28 The Harm-Mitigation Potential of Clean and Improved Cooking Solutions A range of cooking technologies can mitigate these harmful effects, but there is no ideal solution for all users. At the level of an individual cookstove, the potential to address the harms of traditional cooking varies greatly by impact objective, cooking technology, and the quality of the specific cookstove. Although a range of basic improved solutions can generate significant fuel and time savings for biomass consumers, climate benefits are harder to capture and are limited to only a subset of clean cooking technologies. In terms of health effects, only the very cleanest cooking solutions can address the severe harms of long-term exposure to HAP. Appendix 1 discusses the relative benefits of improved and clean cooking solutions compared with a traditional biomass stove (e.g., a three-stone fire) for the most common impact dimensions in the literature. While different technologies have their own advantages, there is no universally applicable answer to the challenges of solid-fuel cooking. The ideal solution will vary based on market circumstances and on the social impact deemed most important. Even when the relative benefits of different solutions are clear, extrapolating from the features of an individual stove to market-level impact potential is difficult due to the complicating factors of stove and fuel affordability and consumers’ willingness to adopt a specific technology. Many of the cleanest solutions from a health standpoint (e.g., biogas, LPG, electricity), which feature quick cooking times and other desirable features, such as safety and durability, are also the most expensive, limiting their uptake at 26 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report scale. Cleaner solutions, on the whole, also require more behavior change on the part of the consumer relative to baseline cooking technologies. Therefore, any generalizations about the best solution must also take into account an assessment of the possibility of adoption at scale. The following sections review in more detail what we currently know about the cooking solutions available in the African market in terms of economic benefits, environmental and climate change benefits, and health effects. Economic Benefits Fuel savings are both the most achievable and the most tangible benefit of clean and improved cooking solutions. Program evaluations and randomized controlled trials (RCTs) in Africa show that, while “legacy” biomass chimney cookstoves typically generate limited fuel savings under real-world conditions over long time periods,29 well-designed, basic ICS can lead to meaningful savings in fuel and collection time. These savings are in the range of 20–35%,30 and 35–65% for the portable wood and charcoal intermediate ICS that are the focus of large-scale Africa distribution efforts by such companies as Envirofit, Ezy Stove, EcoZoom, and Burn Manufacturing.31 Results for intermediate built-in brick and mud rocket ICS of the type that have been distributed at scale in such countries as Kenya and Uganda are comparable.32 Self-reported field evidence from Africa suggests that advanced biomass ICS (i.e., fan-gasifier stoves) can match or exceed the fuel-saving levels of intermediate ICS technologies (40–80%), particularly when paired with well- calibrated renewable pellet fuels. Savings of 50–65% are reported for fan-gasifier stoves using standard (i.e., chunky biomass) fuel and more than 70% for a number of ND gasifier models.33 Actual savings at the household level over time tend to be lower than such figures suggest because, in most cases, households continue to cook with traditional stoves alongside the new solutions. For modern and (non- biomass) renewable cooking technologies—for instance, where full transition to the new stove and fuel should theoretically eliminate solid-fuel use entirely—actual results in SSA pilots are more modest due to baseline technology persistence (e.g., 30–70% biomass fuel savings for users transitioning to LPG, 66–80% for biogas, and 10–40% for solar).34 From the end user’s perspective, the relative affordability and lifetime cooking costs of various solutions are in many ways an even more important dimension than relative fuel savings. Even if full adoption of LPG can help eliminate household spending on inefficient and harmful charcoal, for instance, this will mean little if the household is unable to afford the upfront costs of an LPG stove and cylinder or the ongoing costs of cooking with this fuel. Africa-wide averages and the range of costs for key stoves and fuels are demonstrated in Figure 10. Electricity is, on average, the most expensive fuel from a total cost perspective, followed by charcoal cooking with traditional stoves, and LPG. Renewable solutions, such as biogas and solar (not shown, as the stove does not entail any fuel costs), have the lowest life-cycle costs. The tradeoffs between upfront costs and lifetime cooking costs are explored in more depth later in the report in Figure 44. 27 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report 10: Stove and Figure Unsubsidized fuel costs upfront Africa inof price (2012) solutions (US$ average and market range) SSA cooking Unsubsidized upfront price of SSA cooking solutions (US$ average and market range) 0 25 50 75 100 500 1,400 Unsubsidized upfront price of SSA cooking solutions (US$ average and market range) Biogas digester 0 25 50 75 100 500 1,400 ACS—fan draft Biogas digester 0 25 50 75 100 500 1,400 Ethanol stove ACS—fan draft Solar Biogas cooker digester Ethanol stove LPG stove (w/ cylinder) ACS—fan draft Solar cooker Charcoal intermediate Ethanol stoveICS LPG stove (w/ cylinder) Electric stove Solar cooker Charcoal intermediate ICS Wood rocket (intermediate LPG stove ICS) (w/ cylinder) Electric stove Built-in intermediate ICS) rocket (intermediate Charcoal ICS Wood rocket (intermediate ICS) ACSnatural draft Electric stove Built-in rocket (intermediate ICS) Charcoal basic Wood rocket (intermediate ICS ICS) ACSnatural draft Wood basic Built-in rocket (intermediate ICS ICS) Charcoal basic ICS Traditional biomass stove ACSnatural draft Wood basic ICS Charcoal basic ICS Traditional biomass stove Wood basic ICS Traditional biomass stove Annual cost (in US$) of using cooking solution (SSA average and range)1 Annual cost (in US$) of using cooking solution (SSA average and range)1 Electric stove 310 (50840) Annual cost Traditional (in US$) charcoal of using cooking solution (SSA average and range)1 stove 265 (85510) Electric stove 310 (50840) LPG stove 233 (155460) Traditional charcoal stove 265 (85510) Charcoal basic Electric ICS stove 194 (65370) 310 (50840) LPG stove 233 (155460) Ethanolstove Traditional charcoal stove 191 (115380) 265 (85510) Charcoal basic ICS 194 (65370) Traditional wood LPG (open fire) stove 184 (55580) 233 (155460) Ethanol stove 191 (115380) High-end Charcoal charcoal ICS basic ICS 139 (50275) 194 (65370) Traditional wood (open fire) 184 (55580) Wood Ethanolbasic ICS stove 131 (40200) 191 (115380) High-end charcoal ICS 139 (50275) Natural-draft Traditional woodgasifier ACS (open fire) 107 (30160) 184 (55580) Wood basic ICS 131 (40200) 96 (30145) Wood rocket charcoal ICS) (intermediate High-end ICS 139 (50275) Natural-draft gasifier ACS 107 (30160) Built-in rocket (intermediate Wood basic ICS) ICS 95 (30150) 131 (40200) Wood rocket (intermediate ICS) 96 (30145) Fangasifier Natural-draft ACS gasifierACS 90 (30130) 107 (30160) Built-in rocket (intermediate ICS)2 95 (30150) Biogas Wood rocket digester system (intermediate ICS) (40110) 80 96 (30145) Fan gasifier ACS 90 (30130) Built-in rocket (intermediate ICS) 95 (30150) Biogas digester system2 80 (40110) Fan gasifier ACS 90 (30130) Biogas digester system2 80 (40110) 1 Includes fuel consumption equivalent to 320 megajoules (MJ) and stove price amortized over average stove life. For less commonly used fuels, such as electricity and LPG, average costs are calculated only from countries where usage of fuel is signi cant. 1 Assumesfuel 2Includes range from 10equivalent life consumption to 20 yearsto 320 and megajoules includes (MJ) US$10 20 and stove for price annually amortized over average stove life. For less commonly used fuels, such as servicing/maintenance. electricity and LPG, Sources: Dalberg average costs cookstove are calculated database; only interviews; manufacturer from countries where press usage of fuel is signi cant. searches. 2 Includes 1 Assumesfuel consumption life range from 10equivalent to 20 yearsto 320 and megajoules includes US$10 20and (MJ) stove for annually price amortized over average stove life. For less commonly used fuels, such as servicing/maintenance. electricity and LPG, average costs are calculated only from countries where usage of fuel is signi cant. Sources: Dalberg cookstove database; manufacturer interviews; press searches. 2 Assumes life range from 10 to 20 years and includes US$10 20 annually for servicing/maintenance. Sources: Dalberg cookstove database; manufacturer interviews; press searches. Environmental and Climate Change Benefits Environmental and climate change benefits are more challenging both to realize and to measure. Although there is some evidence that fuel-efficient biomass cookstoves have reduced net woodfuel consumption in such countries as Senegal, the scale of ultimate environmental impacts is unclear, given the limited empirical data on woodfuel consumption and forest degradation. For climate change, the impact of basic and intermediate biomass ICS is likewise uncertain, since many types of improved cookstoves either fail to meaningfully decrease or, in the case of some rocket stoves, actually increase net climate-forcing GHG emissions once BC and other non-Kyoto PICs are included in the calculation. Among biomass solutions, biomass gasifier cookstoves hold the greatest promise for climate change mitigation, given their large reductions in BC emissions (85–95%). However, more field data are needed to fully understand their net climatic impacts. For modern energy, the climate emission benefits of LPG and electric cookstoves are substantial at the point of fuel consumption, but are complicated by the climate costs of fossil-fuel and electricity production—which reduce and, in some cases, may cancel out the benefits of using low-emission modern energy sources. When adoption issues can be surmounted, renewable biogas and solar have the best 28 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report overall environmental and climate change outcomes, but the two technologies have thus far seen little success in Africa. Health EFFECTS Health impacts for such serious conditions as ALRI, COPD, and cardiovascular disease are the most difficult benefit to achieve. This is because meaningful reductions in HAP-linked morbidity and mortality require disproportionately large reductions in emissions due to the steep slope of the exposure response curve for particulate emissions (Figure 11). The bottom of Figure 11, based on the best evidence available, explores the likely mapping of common improved and clean cooking technologies in Africa against this dose-response curve. LPG, electricity, biogas, and solar generate the highest particulate matter (PM) emission reductions vis-à-vis open wood fires (90–99%).35 Ethanol cookstoves likewise enable significant emission reductions (85–95%) based on field trials in Madagascar, but have not yet been conclusively linked to improved health outcomes.36 For biomass cooking, only well-performing fan gasifiers and, to a lesser extent, natural-draft gasifier stoves approach the emission levels of LPG and hold the potential to significantly reduce the incidence and severity of HAP-linked illnesses.37 Even the best of these gasifier technologies cannot yet fully match the performance of gas stoves, however,38 and a number of questions about the emission abatement potential of gasifier stoves for small PM remain unanswered. The search is currently on for a biomass gasifier stove that can achieve an IWA Tier 4 rating for emissions. A number of research and development (R&D) initiatives are in place, and there is optimism from some sector stakeholders that such a technology can be developed and piloted within the next two to five years.39 Figure 11: Exposure response curve for particulate matter emissions (PM2.5) WHO air WHO The steep PM2.5 exposure response curve means that quality Interim even intermediate wood rocket ICS leave ~80% of HAP guidelines: (IT1) target: burden unaddressed 10 µg/m3 35 µg/m3 3x Risk of Child Pneumonia 2x 1x 10 35 125 200 500 ug/m3 Charcoal ICS Solar, LPG Unvented wood rocket ICS Fan wood ACS Electricity, Open fire/ Biogas Ethanol, kerosene 3-stone fire Chimney wood Basic biomass ICS Natural-draft ACS rocket ICS PM2.5 Exposure (µg/m3) in a 24-hour period Note: A comprehensive set of PM2.5 µg/m3 data for all Africa stove technologies is not available, so the relative positioning is meant to be directional. Sources: Adapted from Burnett et al. (2014); Jetter et al. (2012); Grieshop et al. (2011); Dalberg analysis. 29 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report What is already clear is that non-gasifier biomass cooking solutions are likely to have limited positive health effects. Vented (i.e., chimney) rocket stoves under ideal circumstances and with full adoption can likely have small but material health benefits (e.g., a 60% PM reduction leading to reductions of 20–35% in respiratory illness, based on evaluation results in Guatemala).40 Unvented basic ICS and rocket ICS—this includes nearly all stoves promoted in current African cookstove programs and carbon finance projects—likely have no or minimal impact on serious health conditions. These technologies are not, however, entirely without health merit, because improvements in minor maladies, such as eye irritation, headaches, and respiratory discomfort, are widely reported by basic ICS users and supported by mini-RCT data.41 Broader claims about the health benefits of ICS solutions in Africa must be interpreted with caution. Combining the Health and Climate Dimensions Combining potential health and climate impacts of stove emissions, Figure 12 illustrates the directional impacts of the most common SSA cooking solutions, with the white dotted zone lines indicating approximate provisional ISO/IWA emission tiers. The horizontal axis shows the relative health performance of different stove technologies, while the vertical axis focuses on the global warming potential of each technology. The resulting positioning of different solutions requires several qualifications. First, the high health rating of kerosene is deceptive, as the analysis does not account for many harmful particles of kerosene combustion, such as polycyclic hydrocarbons. The climate impacts shown for fossil fuels reflect emissions only at the point of fuel consumption (i.e., emissions from the cookstove during the cooking process), whereas actual climate- warming impacts can be much more negative, particularly in cases where the fuel is produced via inefficient methods (e.g., electricity generated via traditional charcoal-powered plants). It is also important to note that the averages shown in Figure 12 may obscure the wide range of emission performance for these technologies, as can be seen in Appendix 11. Figure 12: Comparative performance of “average” stoves on health and climate impact dimensions Green 0 1 2 3 4 Solar Biogas LPG3 Ethanol Electric3 Fan gasifier Kerosene4 Natural-draft gasifier Basic Built-in rocket Climate Impact1 efficient Portable wood rocket High-end charcoal 3-stone fire Mid-range charcoal Vented coal stove Basic charcoal ICS Coal traditional Polluting Charcoal traditional Unhealthy Clean Health impact2 1. Index on scale of 1 10 based on stove emissions of tons of GHG CO2-eq., including all particles from fuel combustion and charcoal production weighted at global warming potential (GWP)100; assumes fNRB of 0.5. 2. Index on scale of 1 10 of daily PM2.5 intake per person and carbon monoxide (CO) concentration, weighted 80/20 to re ect the more deleterious e ects of particulate emissions relative to CO . 3. Climate impact of electric and LPG stoves only includes CO and particulate emissions at point of fuel consumption; production of these fuels may have signi cantly negative climate e ects e.g., in the case of electricity production from coal combustion but such climate costs vary across countries and are di cult to estimate. 4. Kerosene stove results re ect measured PM and CO emissions and do not incorporate potential kerosene carcinogen e ects. Note: The ISO tiers indicated in red correspond roughly to the ISO/IWA tiers for emissions. Sources: Berkeley Air Monitoring Stove Performance Inventory Report (October 2012); Grieshop et al. (2011); Dalberg stove database; Dalberg analysis. 30 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report © BioLite/2014 Even with such qualifications in mind, Figure 12 makes it clear that—in the case of full displacement of baseline technologies by the new cooking solution—such technologies as solar, biogas, LPG, electric stoves, and to a lesser extent fan- and ND gasifier stoves (ACS) produce the best health and climate outcomes. Regrettably, as Figure 13 shows, in most instances the cleanest and greenest cooking solutions are also the ones that have either higher upfront costs or higher lifetime usage costs, or both. Achieving significantly greater penetration of clean cooking technologies will therefore require either (1) improving the affordability of existing clean cooking solutions (e.g., via financing to reduce upfront costs and, potentially, subsidies to improve ongoing affordability), or (2) creating lower-cost variants of stove and fuel technologies. Currently, from an annualized cost perspective, using modern-fuel and renewable biofuel solutions, such as LPG, electricity, kerosene, and ethanol, results in very high costs that are unaffordable for the vast majority of Africans. Basic and intermediate biomass ICS (shown in light and dark blue) have low-to-moderate annualized usage costs, but also—with the exception of the highest-performing charcoal stoves—limited health benefits. Clean solutions, such as solar and biogas, and near-clean solutions, such as fan- and ND gasifiers (ACS), have relative low annualized costs. However, as is clear from the second chart in Figure 13, many of these solutions are still unaffordable for the majority of African consumers in the absence of financing or subsidies, given their high upfront costs. The way forward must therefore involve either increased clean stove affordability or the continued migration of lower-cost biomass solutions to higher levels of emission performance. 31 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Figure 13: Relationship between cooking solution performance (HAP emissions) and cost $300 Electric Avg. annualized SSA cooking costs (US$)1 Traditional charcoal LPG $200 Basic Kerosene charcoal Ethanol 3-stone fire Mid-range charcoal Coal traditional High-end charcoal Basic $100 wood ICS Portable ND gasifier wood Chimney rocket wood Fan gasifier rocket Biogas Solar 0 Unhealthy Clean Health impact2 Biogas 1,000+ 100 Avg. upfront SSA cost of stove (US$) Fan gasifier Improve performance of ICS and ACS 75 Lower costs of clean cooking solutions Ethanol Electric 50 High-end LPG Solar charcoal Mid-range charcoal 25 Portable Chimney Affordability wood rocket ND gasifier barrier wood rocket Traditional coal Kerosene Basic charcoal Basic wood ICS Traditional charcoal 3-stone fire Policy cut-off for Tier 4 HAP emissions Health impact2 1. Annualized cooking solution costs are based on average fuel costs across Africa, average cooking solution lifespan, and average e ciency. 2. Health rating blends PM2.5 and CO emission performance are based on externally validated controlled cooking test and eld data for dozens of African stoves, triangulated with performance catalog from Berkeley Air Monitoring Group (2012). Sources: Africa stove price database; cooking solution performance database drawing on Berkeley Air Monitoring (2012), Jetter et al. (2012), and Grieshop et al. (2011) data; the conceptual layout draws on an analysis from Dr. Kirk Smith et al. (2014); Dalberg team analysis. 32 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report © Inyenyeri/A Rwandan Social Benefit Company/2014 33 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report 34 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report © Envirofit International/www.envirofit.org/2014 Demand for Clean and Improved Cooking Solutions chapter 2 35 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Demand for Clean and Improved Cooking Solutions Although the case for deploying clean and improved cooking solutions in SSA grows stronger by the day, there is still little comparable, up-to-date information on the African cooking fuel and stove demand landscape. This chapter reviews trends in the region’s cooking fuel mix and fuel demand, provides a forecast for fuel demand, progresses to an in-depth segmentation of the African cooking consumer, and then concludes with an overview of key cooking demand drivers and barriers specific to the region. Demand Landscape for Household Cooking Fuels The share of SSA households dependent on solid fuels stands at 82%, the highest level among developing regions (Figure 14).42 Globally, the use of solid fuels for cooking has declined from 50% to 40% of households since 2000; in Africa, by contrast, it has stagnated at more than 80% since at least the mid-1990s.43 In such countries as Ethiopia, Kenya, Madagascar, Nigeria, Senegal, Tanzania, and Zimbabwe, longitudinal survey data show that demand for modern fuels has declined in relative and even absolute terms in recent years because of rapid population growth, escalating fuel costs, and fuel supply interruptions.44 This has resulted in the rapid growth of biomass-dependent households. Figure 14: Solid- and modern-fuel usage, by global region (2012) Percentage of developing world population relying on solid fuels by region Percentage of developing world population relying on solid fuels by region Solid fuels Solid fuels Modern fuels Modern fuels Total population Rural population Urban population Total population Rural population Urban population Sub-Saharan Africa 82 18 95 5 62 38 Sub-Saharan Africa 82 18 95 5 62 38 South Asia 71 29 88 12 27 73 South Asia 71 29 88 12 27 73 East Asia (cooking and heating)1 70 30 76 24 44 56 East Asia (cooking and heating)1 70 30 76 24 44 56 East Asia (cooking only)2 49 51 68 32 29 71 East Asia (cooking only)2 49 51 68 32 29 71 Southeast Asia 53 47 77 23 28 72 Southeast Asia 53 47 77 23 28 72 Latin America & Caribbean 19 81 58 42 8 92 Latin America & Caribbean 19 81 58 42 8 92 Eastern Europe & Eastern Europe & 17 83 31 69 6 94 Central Asia 17 83 31 69 6 94 Central Asia Sources: WHO Global Health Data Respository, DHS, MICS, LSMS, National Census data; Dalberg analysis Sources: WHO Global Health Data Respository, DHS, MICS, LSMS, National Census data; Dalberg analysis Note: Figures are latest available, roughly equivalent to 2012-2013 average, based on 2005-2014 data for individual countries. Note: Figures are latest available, roughly equivalent to 2012-2013 average, based on 2005-2014 data for individual countries. 36 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report The level of solid-fuel dependence varies across SSA countries and between rural and urban areas. As Figure 15 shows, across SSA, wood (66%) and charcoal (13%) are the primary cooking fuels, followed by kerosene (7%), electricity (6%), and LPG (5%). The “other” category in the figure includes a number of other notable fuels. Although animal dung plays a minor role in the region overall (less than 1.2%), it is locally important in such countries as Ethiopia, Lesotho, and Senegal. Coal use is likewise low in the region (1.2%) in absolute terms , but is locally important in such countries as South Africa and Sudan. Figure 15: SSA primary cooking-fuel mix, by subregion and rural/urban area SSA “primary” household fuel mix by type in 2010 (population in millions, % share) 854 M 328 M 526 M 2% 6% 3% 1% Electricity 5% 12% 6% LPG 7% 10% Kerosene 13% Charcoal 14% Wood Other1 27% 85% 66% 33% 4% 4% 3% Total Urban Rural 1 Other primarily includes solid fuels like dung, crop waste, and coal, alongside small populations of natural gas and biogas users. Sources: Dalberg fuel use database drawing on WHO fuels database, and DHS, MICS, LSMS, national census, and energy audit 2005–12 data. Share of population using different types of fuels as primary cooking fuel, 2010 Urban Sub-Saharan Africa Rural Sub-Saharan Africa 70 59 139 64 232 39 179 76 9% 3% 3% 3% 6% 1% 2% 2% Other 8% 8% 5% 13% 5% Charcoal 20% Wood 41% 12% Electricity 43% Gas Kerosene 40% 73% 49% 87% 91% 85% 41% 1% 30% 11% 1% 9% 7% 19% 10% 25% 2% 9% 6% 1% 0% 2% 3% 4% 8% East Central West Southern East Central West Southern Africa Africa Africa Africa Africa` Africa Africa Africa Note: Total countries pro led: 45; Central Africa=4; East Africa=12; West Africa=19; Southern Africa=10. Sources: Dalberg fuels database drawing on WHO Global Health Data repository and additoinal surveys; Dalberg analysis. 37 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report The use of crop waste for cooking is widespread, particularly in West Africa, but is typically captured under wood biomass or “other” categories in survey statistics and, therefore, is difficult to quantify. As a general trend, solid-fuel use predominates in rural areas; only 6% of rural households rely on modern fuels for their primary cooking needs, as opposed to 36% of households in urban areas. By subregion, solid-fuel dependence is most acute in East and Central Africa. However, even in Southern Africa and West Africa, where urban modern-fuel penetration is moderate to high, the vast majority of rural households continue to depend on biomass cooking (Figure 15). The situation is particularly dire in a quarter of SSA countries, where more than 98% of all households cook exclusively with solid fuels. Primary fuel data must be interpreted with caution—there are more modern-fuel users in Africa than is usually assumed, but the number of exclusive users of modern cooking fuels is very small. Even when SSA households own modern-fuel stoves, many continue to use traditional or minimally improved biomass stoves in parallel—a practice called “stove stacking.”45 Fuel and stove stacking are the rule across developing Africa. In Botswana, for instance, a reported 75% of modern-fuel households use wood alongside their modern-fuel stoves.46 Half of the households in rural and urban southwestern Nigeria combine modern (kerosene and LPG) and traditional cooking solutions.47 Similar ratios have been reported in surveys in Burkina Faso, Ghana, Kenya, and Senegal.48 On one hand, this level of fuel and stove stacking suggests that the demand for clean modern fuels is much broader in Africa than indicated by primary fuel data—such fuels as LPG, electricity, and kerosene likely reach 20–50% more households than primary modern-fuel cookstove numbers indicate.49 On the other hand, many of these households continue to use traditional or minimally improved biomass stoves, thus losing many of the benefits of clean cooking because even moderate exposure to particulate emissions leads to serious long-term health effects. The number of households that use clean modern fuels, such as LPG and electricity, exclusively is likely less than 5% of the SSA population. The population relying on solid fuels in Africa is expected to further increase toward the end of this decade. Historical fuel mix trends and demographic drivers, such as population growth, suggest that the number of Africans relying on solid fuels as a primary fuel will grow to 850–900 million by 2020 (Figure 16).50 Even in scenarios of successful modern and renewable fuel scale-up, such as the achievement of the Global LPG Partnership’s target of 70 million new African LPG users by 2018 and the Africa Biogas Partnership’s target of biogas access for 10 million people by 2020, the SSA solid-fuel population would still be significantly higher than today (>750 million).51 Within this overall trend of persisting solid-fuel reliance, historical fuel-mix data suggest that charcoal will constitute a growing share of solid-fuel demand and, within the modern-fuel sector, LPG and electricity will continue to take shares from kerosene users—important news in light of increasing evidence about the harms of kerosene cooking (Figure 17). 38 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Figure 16: Historical trends and forecast for the global solid-fuel population Number of people living in households where the primary fuel is a solid fuel (in millions)2 ∆ 20102020 2,883 2,912 2,951 (millions) SSA 2,780 South Asia 706 786 885 +180 556 East Asia Southeast Asia Solid fuel use drivers Latin America & Caribbean • Population growth 1,079 1,139 • Urbanization 1,139 1,152 +13 • Inertial fuel adoption trends • Incomes1 • Price differential between fuels1 • Government policy changes1 775 660 612 538 122 281 293 291 293 0 89 85 84 83 2 2000 2010 2015 2020 forecast forecast 1. Factors considered qualitatively, but not modeled directly for the forecast. 2. Data set covers 82 countries accounting for 98% of solid-fuel users globally i.e., actual number of solid-fuel users likely close to ~3.1 billion in 2010 if both solid fuel cooking and heating households are included. Sources: 2000 15 data based on WHO, DHS, MICS, LSMS, and national survey data; projection based on inertial penetration trends adjusted for changes in urban/rural mix. Figure 17: Historical and projected SSA fuel mix Historical and projected SSA cooking fuel mix (million households, percentage) 133 171 191 215 4.6% 5.6% 6.0% 6.4% Electricity 3.6% 4.6% 5.0% 5.5% LPG 8.2% 6.8% 5.7% 4.5% Kerosene 9.1% 13.1% 17.0% Charcoal 19.8% Wood Other 69.8% 66.0% 62.6% 60.3% 4.7% 3.9% 3.6% 3.6% 2000 2010 2015 forecast 2020 forecast Source: Dalberg projection based on inertial penetration trends for underlying fuels from 2000 to 2013, adjusted for changes in population and urban/rural mix (see Appendix 5). 39 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Against this background of persisting reliance on solid fuels, high and rising fuel prices will be a major demand driver for fuel-efficient biomass ICS and clean-fuel alternatives. Over 2000–2010 time period, in nominal terms, LPG prices have risen 8% annually for key Africa LPG markets (11% globally); kerosene prices have grown 9% annually; electricity costs have grown more slowly, but vastly exceed the cost of other cooking fuels in most markets; and the price of ethanol, a potential alternative cooking fuel, has remained above that of kerosene.52 Because of increasing demand and growing biomass scarcity, however, charcoal prices have grown even faster—more than tripling in a decade (>11% annual growth). This long-term trend in fuel pricing has held steady over the long term, with a recent spike in fossil fuel prices in 2013-2014 compensated with moderate (10-20%) price decline for LPG and kerosene in late 2014-early 2015. Though fuel prices vary at the country level, as of 2011 the average cost of cooking exclusively with charcoal across the SSA region exceeded the costs of cooking with LPG and kerosene (Figure 18). This is particularly the case for the urban poor, who pay 25–70% premiums (45% on average) for their small-unit charcoal purchases.53 Although firewood continues to be the cheapest cooking option overall, anecdotal evidence suggests that in at least some geographies wood scarcity is increasing—with rising firewood prices, a greater share of firewood- using households purchasing their wood, and longer collection times for firewood gatherers. Aside from continuing to increase energy poverty, in the years to come these trends should improve the appeal of modern fuels, increase demand for cookstoves that can save on biomass fuel, and improve the business case for such sustainable alternatives as renewable biomass briquettes, biofuels, and biogas. Figure 18: Historical fuel cost for the average household in SSA Average household cooking by fuel using constant fuel diet (avg. real cost of 320-MJ cooking energy consumption in 2012 US$) 400 Charcoal (w/ 45% poverty 350 premium) 300 Charcoal (kg) LPG (kg) 250 Kerosene (l) 200 Wood (kg) 150 100 50 2000 2001 2002 2003 2004 2005 2006 2007 2008 2008 2010 2011 2012 Note: This trend has continued through 2013-2015, with average retail LPG prices per kg declining ~15% from their 2012 peak while charcoal prices continue to stagnate or rise depending on geography. Source: Dalberg SSA fuel price database (22 countries for charcoal, 11 for LPG, 45 for kerosene). Fueled by these trends, the absolute size of the SSA cooking fuel and stove market will grow quickly. In 2010 alone, consumers spent US$20 billion across all cooking fuels in SSA—an amount that will grow to an annual expenditure of more than US$47 billion by 2020, with such traditional fuels as charcoal and wood accounting for more than half of this total (Figure 19).54 40 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Figure 19: SSA annual household spending on cooking fuels (US$ billions) Annual historical and projected SSA household spending on cooking fuels US$40 billion Wood 9 Charcoal LPG Kerosene Electricity Other 20 US$20 billion 6 5 6 5 2 2 7 3 <0.5 <0.5 2010 2020 forecast 1 Based on inertial scenario, which assumes no major shifts in fuel-use patterns toward modern or renewable fuels. Excludes use of fuel for noncooking purposes (e.g., space heating), and excludes nonresidential fuel use (e.g., charcoal use by small industry and commercial sector). Does include fuel spending for lighting . 2 Calculation based on number of households using fuel as “primary” cooking fuel multiplied by average SS fuel price and averave consumption required for 320-MJ diet (i.e., 2.5 meals per day) Source: Dalberg SSA cooking fuel market-sizing and forecast model. Although fuel markets are magnitudes larger than the market for cooking appliances, spending on stoves is significant and growing. Annual SSA consumer spending on cooking appliances (across all traditional, clean, and improved technologies) is likely in the US$300–400 million range today out of a global stove appliance market of less than US$8 billion in the developing world.55 The SSA market is small compared with global stove sales, because of much lower SSA access to modern-fuel stoves, and the low Africa penetration of biogas digesters (US$300–1,500 globally), which drive much of the annual spending on cooking energy appliances (e.g., 5–7 million new biogas digesters were deployed in China alone in 2012). The large scale of the African cooking fuel markets makes it clear that SSA consumers are already spending significant funds on cooking on an annual basis. Furthermore, the relative scale of cooking fuel and appliance markets highlights the size of the opportunity for those private-sector players that go beyond stove appliance sales and are able to develop effective cooking-fuel production and delivery models (e.g., green charcoal and crop-waste briquettes, ethanol, methanol, or LPG). African Cooking Consumer Segmentation End-user demand and product preferences vary significantly across SSA customer segments. African consumers are an extremely diverse group, with a range of preferences across fuel types and stove designs. Although generalizations at the scale of a continent necessarily obscure regional- and country-level variation, it is nonetheless illuminating to divide the African consumer into seven segments based on a combination of income levels, urban versus rural status, fuel use preferences, and fuel procurement approaches (Figure 20).56 These segments fall into four broad groups: wood collectors (labeled in shades of red in the figure), wood purchasers (blue), charcoal users (yellow), and modern-fuel users (green). 41 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Figure 20: Segmentation of the SSA improved and clean cooking consumer Poor Mid-income Poor Mid-income Poor Mid-high- Modern- wood wood wood wood charcoal income fuel collectors collectors purchasers purchasers users charcoal users Segment size (HH) 53 mil (31%) 25 mil (15%) 17 mil (10%) 16 mil (10%) 6 mil (4%) 18 mil (11%) 29 mil (17%) Current spending n/a n/a $1–10/month $5–25/month $5–20/month $5–35/month $5–30/month Monthly fuel cost (stove cost) ($0–5) ($0–5) ($1–5) ($1–12) ($10–70) Household income1 95% BoP 500–1,500 500–1,500 500–1,500, 1,500 40% >1,500 Location of consumer 90% rural, 90% rural, >60% urban, 38% urban, 50% 75% urban, rest >80% 10% urban rest urban esp. W. Africa 62% rural urban peri-urban urban Awareness of solid fuel health harms/risks Awareness of improved fuels/stoves (Physical) access to improved and clean solutions Ability to afford new solutions Access to finance Openness to new technologies Note: Full circles imply higher likelihood of ICS and clean fuel adoption; excludes 6.5 million of “other” households which are primarily constituted of biomass (dung, crop waste, straw) collectors and have characteristics that are comparable with the poor wood collector segment. 1. Utilizes World Resources Institute (WRI) per capita expenditure proxy for household (HH) incomes, e.g., BoP 500 means HHs with expenditures of US$500 per capita monthly. Sources: National income tiered end-user surveys; Shell Foundation; Alliance for Clean Cookstoves market assessments; Dalberg analysis. Familiarity with the key consumer segments and their needs is essential to developing a nuanced understanding of the African clean and improved cooking opportunity. We will here review the segmentation in detail by profiling each of the four broad customer segments. The detailed methodology behind this segmentation is covered in Appendix 6. The subsequent sections then turn to consider cross-cutting Africa demand drivers and constraints, such as stove design, consumers’ willingness to adopt (and pay for) new stoves and fuels, and their ability to afford clean and improved cooking solutions. 42 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Wood Collectors Rural wood collectors, including a small segment of nonwood biomass collectors (i.e., dung and crop waste users), represent roughly half (48%) of African households. Most of these households (about 30% of the SSA total) are extremely poor (BoP <500). Many are subsistence farmers and pastoralists living in remote areas with little or no integration into the modern cash economy. Unsurprisingly, such households are difficult to reach through existing distribution channels. Tradition is important for this segment, and achieving behavior change requires finely tailored solutions. The fuel-saving motivation for most wood collectors is relatively weak, given their lack of direct economic benefits from such savings. Firewood collectors do appreciate the time savings from wood collection that can be achieved by ICS and clean- fuel solutions, but the value placed on time savings by male household heads may not be high when the costs are borne disproportionately by women and girls. Although the avoidance of the immediate consequences of indoor smoke, such as coughing and eye irritation, is important to women in this segment, the longer-term health effects are rarely understood and scarcely valued. Middle-income (BoP 500–1,500) fuel-collector households (15% of the SSA market, or a third of this segment) can be persuaded to adopt and pay for improved stoves, given their greater means, educational levels, and greater exposure to markets. For the poorest wood collectors, however, ensuring adoption of improved solutions requires significant investment in behavior change and very low or, in some cases, fully subsidized ICS costs. Wood Purchasers Wood purchasers, including middle-income and low-income wood buyers, constitute 20% of African households. A third of SSA households use wood as a primary fuel (Figure 21). While the overall share of households cooking with wood will decrease by 2020 (Figure 17), the wood-purchasing segment will likely continue to grow as firewood collection becomes more difficult.57 Figure 21: Firewood-purchasing households as a share of all firewood users in Sub-Saharan Africa Share of firewood-using households that purchase their woodfuel (percent) 82% 67% 52% 47% 37% 38% 27% 29% 31% 31% ~30% 22% 23% 19% 15% 12% Ethiopia Malawi Kenya Nigeria Uganda Rwanda Botswana South Africa Mali Tanzania Mozambique Chad Ghana Senegal Niger Sources: Database of 26 surveys (2004 2014) for 12 African countries based on data reported in a range of sources, including fuel and stove program evaluations, rewood market surveys, and national energy census surveys; Dalberg analysis. 43 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Middle-income wood purchasers: Middle-income wood purchasers (10% of SSA) are mostly rural (>60%) and are represented largely by middle-income farming households who can afford to avoid fuel-collection tasks by paying for their wood. There are also large urban populations of middle-income wood buyers who consist of salaried government employees (e.g., teachers), lower-income professionals, and small traders, particularly in West African countries with large commercial urban firewood markets. Although urban households in this segment often have access to modern fuels, such as LPG, kerosene, or electricity, adoption and use are constrained by high fuel costs. Across both rural and urban areas, wood buyers tend to be more socially conservative and risk averse in outlook than comparable charcoal and modern-fuel users, with the result that behavioral challenges to transitioning to new solutions can be substantial. More important than the barriers of custom and tradition, the economics of cleaner cooking are the biggest challenge for this segment, as the leap in costs to modern fuels is large—an increase of 2–5 times relative to the annual costs of cooking with biomass fuels and stoves. The breadth of this gap suggests that, in the absence of large modern-fuel subsidies, fuel-efficient ICS are likely the optimal cooking solution for many households in this segment. For wealthier wood purchasers, clean fuels and wood gasifier stoves are also an option, as their disposable incomes and education make them more amenable to public health messaging. Poor wood purchasers: Poor wood buyers (10% of SSA households), in contrast to the middle-income wood buyers, are primarily urban and are heavily concentrated in West Africa, where there is no tradition of charcoal cooking in most markets and firewood foraging is difficult or impossible near big cities. In urban areas, this segment largely consists of low-wage, informal-sector workers and slum dwellers. In rural areas, households in this segment are typically lower- to middle-income farmers. Many poor wood purchasers (20–40%) resort to markets for only a part of their firewood needs, because purchased wood is often supplemented by wood collection, particularly in rural areas.59 The size of this segment changes seasonally. There is ample anecdotal evidence that fuel purchasing by the African poor increases substantially during periods of heavy rain, when households are unable to collect sufficient firewood themselves.60 Given their income constraints, these households are highly opportunistic and primarily motivated by fuel savings in their choice of cooking solutions. Fuel-efficient ICS, when appropriately designed, can be an attractive solution for these consumers, but their ability to afford ICS is limited and, due to the low cost of firewood, payback periods are likely to be long for all but the most basic ICS. Charcoal Users Africa is characterized by two distinct segments of largely urban households that use charcoal as their primary cooking fuel (24 million households in SSA, 15% of the total)61—the urban charcoal-dependent poor (4%) and middle- to high-income charcoal users (11%). Both of these subsegments will grow quickly.62 Middle-class charcoal users have some disposable income, but are often unable or unwilling to migrate to modern fuels due to cost and access constraints. These consumers constitute a large minority in many of the continent’s urban centers, with many concentrated in African megacities, including Nairobi, Dar es Salaam, Antananarivo, Addis Ababa, Kampala, and Kinshasa in East and Central Africa; Maputo, Lusaka, and Lilongwe in Southern Africa; and Accra, Bamako, Dakar, Luanda, and Abidjan in West Africa.63 While this segment is primarily motivated by value due to the already high and fast-rising costs of charcoal, the cost of stoves and fuels is not the sole driver of demand. Time savings, convenience, durability, and a modern appearance are important features. These consumers can be reached by mainstream urban distribution channels and, like modern-fuel users, already have experience with other consumer durable goods, including relatively high rates of adoption of mobile phones, radios, low-cost televisions, and refrigerators. The middle-income charcoal user segment is likely the most studied and best understood by commercially minded ICS and clean-fuel promoters. It is currently the target market for most of the large urban-ICS and clean stove enterprises in the region, and is the anchor for the vast majority of successful SSA carbon finance projects. This segment also has the highest current penetration of improved and clean cooking technologies, ranging from (1) basic charcoal jiko-style ICS that are the baseline charcoal cooking solution in many big urban markets, to (2) high-performance rocket charcoal stoves in Kenya and Uganda, to (3) competing technologies like ethanol in Mozambique; LPG in markets like Kenya, Ghana, Mali, and Senegal; and electric stoves in South Africa and Ethiopia. The appeal of this segment is not surprising: it combines ease of access for distributors (given the density of urban populations), strong economic incentives for fuel-efficient technologies, and sufficient 44 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report disposable incomes to purchase stoves upfront for cash, including at relatively high price points (US$25–50). Migrating such households to more efficient ICS or, when possible, to clean fuels remains a major commercial opportunity. The poor charcoal user segment is also heavily concentrated in African cities (50% urban), but otherwise has very different needs and preferences. Although these households are part of the modern cash economy, they are some of the poorest (50% 48% 42% 29% 25% 1520% Kenya Burkina Faso Malawi Zambia Uganda Tanzania Malawi Kenya Mozambique Rwanda (Basic (Basic ICS (Portable (Basic (Rocket (Basic (Basic (LPG) (Basic (Wood improved + LPG) wood improved Lorena) improved improved improved rocket) wood) rocket) charcoal) charcoal) wood) wood and charcoal) Sources: Kenya, Malawi, Mozambique, Tanzania, Zambia (ProBEC monitoring and evaluation reports, see, e.g., Schutze 2010); Kenya LPG (Malla et al. 2009); Uganda Rocket Lorena (Malinski 2006); Burkina Faso basic ICS and LPG owners (Bensch et al. 2013); Rwanda EcoZoom wood rocket (Barstow et al. 2014); Dalberg analysis. Affordability and Ability to Pay Although many Africans can theoretically afford at least basic improved cooking solutions, high costs are a critical obstacle for the poor and impede the overall growth of the market. The nature of the affordability challenges varies greatly by cooking technology and consumer segment. For low-cost, basic ICS, affordability and ability to pay are not major issues, except for the very poor. The vast majority of SSA consumers (70–90%)— including many of those who fall below the BoP 500 income tier (less than US$1.25 per day)—are able to afford paying US$3–7 for basic ICS, once they have access to improved stoves and are convinced of the quality and utility of the product.108 At the same time, for many long-established ICS and clean cooking technologies, cookstove and fuel affordability are likely the bigger near-term demand constraints relative to willingness to adopt. The affordability challenge is especially problematic for higher-end cooking appliances and modern fuels,109 where high upfront costs (US$75–100 for biomass fan gasifier stoves, US$50–100 for LPG and electric stove kits, US$500–1,500 for biogas) severely limit the clean cooking market’s potential for the bottom half of the SSA market.110 The challenge is not limited to upfront costs; for such modern fuels as LPG and electricity, the ongoing costs of the fuel can be 4 to 10 times more expensive on an annual basis than purchased firewood. However, when compared with more expensive biomass fuels, such as charcoal, in some cases, modern fuels can be competitive, particularly where they are unsubsidized. The acuteness of the affordability challenge for cookstoves is sometimes dismissed by referencing the high and growing penetration of mobile phones in Africa: more than 70% of SSA adults111 own a US$15–100 mobile phone handset. Matching this level of mobile handset penetration would mean more than tripling the number of SSA households (20%) that currently own intermediate ICS (US$15–30) or clean cooking solutions (US$50–100). The analogy to mobile phone markets must be viewed with extreme caution, however, since the budgets of resource-constrained consumers differ widely for such categories as household energy, housing, food, communications, and entertainment. While a household may be able to afford spending more than the SSA 52 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report average of 7% of its income on household energy in absolute terms, in relative terms incremental spending may be unaffordable, as it would mean reducing already constrained household consumption of vital goods and services, such as food and shelter. Furthermore, while investments in improved and advanced cooking solutions result in qualitative improvements over the traditional stove, the adoption of cell phones allows households access to an entirely new service that had not been previously accessible. Therefore, the value of the improvement is not comparable. Historical purchasing behavior shows the importance of affordability as a factor. Less than 20% of SSA consumers today have spent more than US$15–20 on their primary cookstoves.112 Shell Foundation surveys in Kenya, Tanzania, and Uganda, though somewhat dated, more broadly show that only 10–20% of households in these countries purchased any consumer durable item costing more than US$30 over the course of a year.113 Therefore, the adoption of an intermediate ICS solution in the US$15–30 range implies a significant reallocation of household budget priorities for an average SSA household. The challenge is even greater for clean cookstoves, since the average prices of such clean stove appliances as LPG and biomass fan gasifiers (US$50–100) are higher than the cost of an average SSA mobile phone handset (US$30–50). Furthermore, beyond stove costs, such clean cooking solutions as LPG, electricity, and ethanol have the additional hurdle of high ongoing cooking energy costs.115 In light of the data, it is likely that only the wealthiest 15–20% of SSA consumers can in the near term afford cash purchases of the highest-cost clean cooking solutions (US$50–100) without major saving mobilization or major shifts in consumer preferences.116 Households’ ability to afford intermediate ICS (e.g., industrial rocket stoves) and lower-cost ACS (e.g., ND gasifiers) costing US$15–40 is much higher, but likely is still restricted to less than half of the SSA population under normal circumstances. Addressing Consumers’ Willingness to Pay Willingness to adopt and pay for improved and clean stoves is a function of (1) consumers’ exposure to these technologies and (2) their ability to afford them—or, in other words, the extent to which their “liquidity constraints” can be reduced. This section discusses each of these factors in turn. Increasing Consumer Exposure Willingness to adopt and pay for improved and clean stoves is a function of consumer exposure to these technologies—and can thus be influenced by stove designers and marketers. As noted earlier in Figure 24, a sizable portion of consumers will remain disinclined to convert to cleaner and more efficient cooking technologies in the near term at any stove price. However, the experience of the SSA cookstove sector (and of comparable BoP consumer durable technologies, such as solar lanterns) shows that stove program designers and entrepreneurs have several tools at their disposal to influence consumer WTP. Figure 26: Increasing consumer willingness to pay through exposure Customer willingness to pay for product pre-use vs. post-use (1-week trial) US$ Customer willingness to pay for product pre-use vs. post-use (1-week trial) US$ Customer willingness to pay for product pre-use vs. post-use (1-week trial) US$ Pre-use Uganda Charcoal Stove Tanzania Solar Lantern Experiment1 Pre-use Uganda Charcoal 2Stove Experiment Tanzania Solar Lantern Experiment1 Post-use Pre-use Uganda Charcoal 2Stove Tanzania Solar Lantern Experiment1 Post-use Experiment 35x Post-use Experiment2 35x 35x 2x 33-56 2x 33-56 2x 33-56 1.3x 20 1.3x 20 1.3x 10 20 9 10 3 4 9 10 3 4 9 3 4 Charcoal ICS Torch Light Ambient/ Area Light Charcoal ICS Torch Light Ambient/ Area Light Charcoal ICS Torch Light Ambient/ Area Light 1. Rural Tanzania research (Lighting Africa 2012) 2. Rural 1. Tanzania Extrapolated research from (Lighting results Africa for urban 2012) Uganda randomized controlled trial with Ugastove charcoal stove (Levine et al.. 2012) 1. Extrapolated 2. Rural Tanzania research from (Lighting results Africa for urban 2012) Uganda randomized controlled trial with Ugastove charcoal stove (Levine et al.. 2012) 2. Extrapolated from results for urban Uganda randomized controlled trial with Ugastove charcoal stove (Levine et al.. 2012) 53 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report One important tool is exposure to the new technology. Clean and improved cookstoves are an “experience good,” a product whose benefits are difficult to appreciate prior to consumption.118 Assuming adequate design and performance, WTP for such experience goods as cookstoves, solar lanterns, and malaria bed nets is directly correlated with consumer exposure to the product. Evidence from the field suggests that the exposure effect for cookstoves could be substantial. A large-scale RCT on intermediate charcoal ICS in rural and urban Uganda, for instance, has demonstrated that consumers’ WTP doubles after one week of experience with the stove (Figure 26).119 This is comparable with IFC Lighting Africa research on solar lanterns, where WTP for different types of solar lanterns increased 1.3–5 times after a week of exposure. It is important to note that uptake does not have a linear relationship to exposure. The relative benefits of increased exposure after some initial period will taper off and, in many cases, it is entirely possible for usage levels to fall with increased exposure as consumers learn more about the downsides of the improved technology.120 The “experience good” status of improved and clean cookstoves does mean, however, that as long as the stove is well designed, relative to having no experience with the product, exposure will tend to improve adoption and WTP. Reducing Liquidity Constraints Aside from exposure, there is also significant evidence showing that WTP can be increased by reducing households’ liquidity constraints. In the Uganda study, moving to an installment payment option (four payments over four weeks) led to a twofold increase in WTP. In another large-scale experiment in rural Uganda, which focused on a rocket wood stove, a 42% increase in WTP resulted from moving to weekly installment payments.121 A WTP study for a highly improved charcoal ICS in Mozambique likewise found a 51% increase in WTP by moving to installment payment plans.122 When combined with a free trial, the installment plan option in the Uganda trial shown in Figure 26 led to a twelvefold increase in uptake for both rural and urban consumers, the equivalent of a 250% increase in the price consumers are willing to pay—a phenomenal result.123 A similar twelvefold increase in uptake has been demonstrated for a US$16 wood rocket stove in another large-scale Uganda pilot with a free trial and installment payment approach.124 Aside from installment payments, liquidity constraints to WTP can be minimized by designing and marketing solutions that result in a quick payback period (i.e., the time needed for the savings generated by a new stove to exceed upfront stove costs). Evidence in the literature on both fuel-saving cookstoves and analogous devices, such as solar lanterns, suggests that a target of a two-month or shorter payback period is a strong rule of thumb for minimizing liquidity constraints for the very poor, though the range of acceptable payback for most consumers will likely be between one and six months.125 Such stove economics are feasible only with relatively low-cost solutions and where consumers already pay substantial amounts for their baseline cooking fuels. Other tools for easing liquidity constraints to WTP include providing upfront loans for expensive stoves,126 applying stove-leasing and fuel-utility models in which stoves are provided with little or no cost and the value is recouped through ongoing fuel payments,127 and deploying technology-enabled pay-as-you-go solutions in which the stove can be activated remotely when users pay their cooking utility payment via a mobile payment or account top-up Scratch Card.128 Unfortunately, the transaction costs for many such approaches are high—often prohibitively so, given the capital constraints and relatively low margins of many stove entrepreneurs. Figure 27 reviews the broader set of tools that can be deployed by stove designers and marketers to maximize demand by overcoming WTP and affordability constraints. All of these tools have been noted in the literature anecdotally but, pending further research, their relative value is at this point unclear. While affordability is a challenge, it is clear that the truly nonmarketable population that cannot be reached by lower-cost commercial cooking solutions is small. Identifying likely market sizes for improved and clean cooking solutions requires considering ability and WTP by customer segment. African urban consumers already purchase relatively expensive fuels and can realize immediate economic gains from switching to more efficient cooking solutions. Therefore, they will often show considerable WTP for new stoves within their relative affordability constraints. 54 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Figure 27: Approaches to improving consumers’ ability and willingness to pay Barriers Key issues Ways to stimulate demand Appropriate stove design • Poor fit with consumer needs, • Adopt a human--centric design cooking behavior, lifestyle approach (ethnographic research, • Negative side effects that negate rapid prototyping) benefits (e.g., long cooking time) • Customize to accommodate needs of different segments • Focus on co-benefit features to boost stove value (e.g., appearance) Trust in vendor and technology • Low confidence in product’s ability • Offer free trial period, live to deliver promised value demonstrations • Low trust in sales channel/ • Use peer pressure/social marketing manufacturer • Co-brand/partner with known entity • Concerns about product durability or trusted individual, (e.g., churches) • Low appetite for risk • Offer easy returns/warranty period Awareness of and appreciation for • Low awareness of new cooking • Conduct consumer education clean cooking benefits technologies campaigns about stove benefits and • Present bias that minimizes potential savings (e.g., visualization appreciation for long-term clean of savings for consumers with low cooking benefits literacy) • Decision makers not motivated by • Bundle product with products that stove benefits (e.g., gender issues) the purchaser values in the near term • Limited decision making by women • Tailor marketing to appeal to benefits for male purchaser, not just the cook • Market co-benefits (e.g., phone charging) Stove and fuel access • Few or no physical locations for • Provide local points of contact to stove purchasing/maintenance reassure consumers about local • Sporadic/unpredictable/low-quality presence (even if fixed locations not fuel supply (e.g., LPG shortages, wet major sales driver) wood, unpredictable pellet prices) • Vertically integrate with stove supply to ensure availability; stockpile fuel supplies Liquidity constraints • Limited disposable income and few • Provide installment payment model if any savings • Provide consumer finance Sources: Levine et al. (2012); Beltramo et al. (2014a and 2014b; Mullainathan and Shafir (2011); Honkalaskar et al. (2013); O’Dell et al. (2013); Miller and Mobarak (2013); Dalberg interviews and analysis. At the same time, most such urban consumers also have moderate, but growing, disposable incomes. When combined, these segments (i.e., most urban modern-fuel and charcoal users) represent nearly a third of SSA households, and should be a prime market for highly efficient and clean stoves and fuels (Figure 28). Evidence from the field supports this hypothesis: the vast majority of profitable, unsubsidized intermediate ICS business models in Africa focus on this segment, given its very high inherent willingness and ability to pay. For instance, surveys in Kenya, even in poor slum areas, show that a significant share of charcoal users are willing to pay more than US$30 for an improved stove—a substantial amount that allows users to purchase relatively high- cost charcoal cookstoves manufactured by such companies as Envirofit and BURN Manufacturing.129 A caveat nonetheless remains: in most countries in Africa, from a mere fuel-savings perspective, the payback periods for such cookstoves can easily exceed an entire year of stove operation.130 55 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Figure 28: SSA population by cooking market segment (primary fuel) Nonwood biomass collectors Fuel collectors Modern fuel 4% 17% Mid- to high- Poor wood collector income charcoal 31% 11% 4% Nonmarketable Poor charcoal population? 10% >15–20% Mid-income 15% wood purchaser 10% Mid-income wood collector Poor wood purchaser Source: Dahlberg analysis. Another 20% of African households rely partly or exclusively on purchased firewood and, theoretically, should also find the fuel-saving value proposition of ICS attractive. The remaining half of the SSA consumer market, however, consists of rural households who collect their biomass (circled with a thick red line in Figure 28). Interviews with program developers and social entrepreneurs who focus on these segments suggest that most of these consumers do not place a high value on the time lost to fuel collection. Therefore, they are less motivated by the fuel-saving potential of improved cookstoves. Even among this rural segment, however, anecdotal data from cookstove entrepreneurs suggest that the uptake of improved stoves could be significant, though more difficult to achieve and requiring lower price points than urban markets. Survey evidence from the Millennium Villages Projects (MVP), for instance, shows that a significant share of consumers in rural Uganda and Tanzania (17–30%) were willing and able to pay US$17.50 or more for quality intermediate ICS (Figure 29).131 This suggests that the absolutely “unmarketable” segment may be much smaller than is usually assumed. It is likely that less than 15–20% of all African consumers will view improved solutions as being absolutely unaffordable or will have no interest in adopting a new stove under any circumstances (see dotted white line segment in Figure 28). This does not mean that WTP challenges for low- and moderately priced ICS are immaterial. The gap between WTP and the fair-market value of such moderately priced technologies as intermediate ICS and ACS can be substantial in rural areas (rocket stove WTP can be 20–50% of a stove’s retail value),132 with many cooking-sector players interviewed for this report describing both psychological and affordability barriers for solutions that greatly exceed an upfront cost of US$10–15. Even if WTP can be improved significantly with exposure and financing for such consumers, this will usually still mean that the cookstove entrepreneur will need to subsidize upfront prices (e.g., by recouping costs from carbon-financing revenue streams) to see significant adoption at scale. 56 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Figure 29: Willingness and ability to pay by segment—example of two SSA villages Rural Tanzania MVP village Rural Uganda MVP village Not Not addressable addressable <5 or not <5 or not ??? 15% ??? 20% interested interested Poor wood Poor wood 38% 47% collectors collectors 510 25% 510 18% Mid-income 26% 1017.5 30% collectors 1017.5 45% Mid-income 31% collectors Wood 36% Wood 17.5+ 30% buyers 17.5+ 17% 22% buyers Willingness to Share purchasing Willingness to Share purchasing pay (US$)1 wood2 pay (US$)1 wood2 1. Data extrapolated from Adkins et al. (2010) an re ects willingness to pay for improved rocket stoves. 2. Data for speci c Millennium Villages Project (MVP) villages not availale. Uganda and Tanzania collector data based on GVEP International assessment of rural areas in each country: mid-income collector share set at 40% to re ect 30 50% range in studies of wood collector demographics in Chad/Sudan/Nepal/Guatemala. Sources: Adkins et al. 2010; GVEP International 2010; Dalberg fuel collection database; Dalberg analysis. 57 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report 58 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report © World Bank/Klas Sander Supply of Clean and Improved Cooking Solutions chapter 3 59 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Cooking Solution Supply Chapter 2 reviewed the main determinants of demand for cooking energy in SSA, including the fuel landscape and consumer preferences. This chapter focuses on how this demand is being served through supply— that is, the manufacturing and distribution of stoves and fuels. Therefore, while it also touches upon issues related to the cooking fuel mix, this chapter examines a different set of questions, including the number of clean and improved stoves currently manufactured and distributed in SSA, their segmentation by type and performance level, and the growth and geographic distribution of stove sales over time.133 It then discusses stove manufacturing models, cooking-sector market structures, product and supplier economics, emerging technology and business model innovations, and distribution approaches. Penetration of Clean and Improved Stoves in Africa Snapshot of Current Stove and Fuel Distribution The penetration of clean cooking energy in the SSA region today is very limited—only one in six Africans has transitioned to clean fuels and cookstoves for the majority of his or her cooking needs. Clean cookstoves— defined for the purposes of this report as stoves running on LPG, electricity, kerosene,134 liquid and gel biofuels, biogas, and solar energy, as well as retained-heat cookers and biomass gasifiers (ACS)—were the primary cooking solutions for only 30 million African households, constituting 17% of the SSA population (Figure 30). In 2010, the SSA penetration of modern-fuel stoves stood at 8 million for LPG/liquefied natural gas (LNG), 10 million for electricity, and less than 12 million for kerosene.135 While the number of Africans using modern-fuel stoves as a secondary cooking solution is not known, estimates from sector experts, triangulated with detailed survey data on multi-fuel use in such markets as Kenya and Senegal, suggest that the total number of African modern-fuel stoves is likely 20–50% higher than the number of primary cooking appliances, translating into 10–12 million LPG, 13–15 million electric, and as many as 15–18 million kerosene stoves.136 ACS and clean renewable cooking alternatives, such as biogas, solar, and liquid biofuels, cumulatively reached less than a half million African families by 2010 and as many as 1.3 million by late 2013.137 The most recent figures available (late 2013/early 2014) show that the penetration of advanced biomass cookstoves is at a very early stage, with 40,000–100,000 natural- and fan-draft gasifiers distributed across pilot project sites in Africa.138 Biogas stoves (about 50,000),139 biofuel (ethanol, methanol, and ethanol gel) stoves (about 350,000),140 and processed solid-fuel briquettes and pellets (about 25,000 end-user households)141 have likewise seen minimal distribution across the region. Solar cookers (about 80,000)142 and retained-heat cooking devices (600,000– 700,000) also have limited penetration.143 In aggregate, these figures overstate the true reach of clean cooking in Africa. As noted earlier in this report, while often categorized as “clean,” a large but unknown share of the SSA kerosene stoves likely should not qualify for the clean cooking designation.144 For many of the clean cooking products, such as solar and retained-heat cookers, an additional complication is that many such solutions are supplemental to existing household stoves (i.e., their adoption rarely means transition to clean cooking). Including all basic and intermediate ICS, penetration of clean and improved cooking solutions is roughly a quarter of the SSA market potential. National surveys and self-reported regional and country-level data sets 60 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Figure 30: Overview of Africa clean and improved stove penetration (2011–2013) Cookstove mixtotal, urban, rural (million HH owning stove, percentage2) 171 105 66 Traditional stoves Legacy ICS Basic and intermediate ICS 51% Kerosene stoves Clean stoves1 71% 83% 12% 5% 14% 7% 7% 8% 22% 4% 10% 2% 3% SSA Total Rural Urban 1. Includes LPG/natural gas (<5%), electricity (<6%), small renewable fuel segment of largely secondary stoves (biogas, solar, ethanol) (<1%), and ACS (<0.1%); kerosene historically categorized with clean modern fuels, but is broken out here given evidence that kerosene’s clean status is questionable in SSA context. 2. Ideal supply metrics would be number of stoves disseminated and number in current use; since this data is not available, “HH with stove ownership” are used as a proxy. Source: 2011–13 SSA market penetration estimate database; Dalberg analysis. from manufacturers, nongovernmental organizations (NGOs), donors, and governments145 suggest that by 2011, 20 million African households owned biomass stoves that met the broadest possible definition of an improved cookstove.146 This grand total included 7.4 million households with basic ICS and 4.4 million with intermediate ICS; another 8 million households cooked with legacy stoves. Accounting for multiple basic ICS stoves per household, the total number of improved and legacy stoves on the SSA market was likely in the 20–22 million range.147 This is roughly 10% of the more than 200 million legacy and improved solid-fuel cookstoves globally.148 The remainder of biomass-dependent Africans use traditional unimproved biomass stoves as their primary cooking device. Although most of these are home-built, three-stone fires (more than 75% of all traditional stoves) and unvented mud stoves, the traditional stove category also includes 15–30 million low-cost (US$0.5–5) metal unimproved charcoal stoves—like the malgache stoves in Burkina Faso and unimproved metal coal pots in Ghana—that are typically purchased by households directly from artisanal producers in village markets.149 Excluding the legacy stove segment for conservatism (because such stoves are unlikely to offer measurably stronger performance than traditional cooking solutions),150 the aggregate penetration of improved stoves was 7%, for a total clean and improved 2010–11 penetration of 24% of all SSA households. As explored in the following section, the share of clean and improved stoves is growing and may surpass 27% by 2013. Cookstove Market Dynamics The SSA clean and improved cookstove market is seeing strong overall growth; LPG and electric stoves are gaining share, and dissemination of intermediate and basic ICS is growing rapidly. Most segments of the SSA market for clean and improved cooking solutions are growing more rapidly than the region’s population at large. Figure 31 provides an overview of the growth trends for major SSA cooking technologies extrapolated from self-reported sales data from dozens of stove manufacturers, distributors, and cookstove programs. These trends show that individual stove market segments are growing quickly.151 61 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Figure 31: Current Africa sales and forward-looking trends, by stove technology Stove type Stoves in Annual SSA Sales Key sales/ market, sales in 2013 growth distribution trends 2011 (2013) (% y-on-y) Legacy 8.1 mil N/A –5% to • Basic chimney-stove promotion efforts slowing across (7.5 mil) Not a commercial 2.5% region, but construction of traditional chimney stoves market likely keeping pace with population growth in rural areas • DHS/MICS time series suggest that legacy chimney stoves are being abandoned at an increasing pace Basic wood 7.5–10 mil 4–6 million units, Wood: • Strong commercial market dynamics for charcoal ICS and charcoal (11–14 mil) largely charcoal 10–15% sales in key East and West African markets (e.g., Ghana, ICS stoves Charcoal: Kenya, Senegal, Tanzania); very wide range of quality 20–30% on charcoal ICS • Wood market growth much slower and largely driven by donor dissemination efforts, rather than market forces, e.g., EnDev Intermediate 4 mil 2–2.5 million 20–50% • Very rapid growth driven by carbon revenue streams; ICS (wood) (8 mil) built-in stoves leading players have 35–80% annual wood rocket 150–200k sales growth portable rocket • Growth in built-in rocket stove dissemination and stoves some portable stoves driven by donor funding; post- intervention trajectory unclear Intermediate 0.1 mil 300–400k, 30–80% • Growth driven both by strong margins for sellers ICS (charcoal) (0.6 mil) depending (due to high demand and ability to pay from urban on whether charcoal consumers) and additional incentives from semi-industrial carbon finance revenues charcoal ICS • 30–200% annual sales growth for individual leading included players ACS 10–50k 20k per year n/a • Technology and business models currently at pilot (40–100k) distributed for stage market pilots LPG 8–12 mil 1–2 million 5% • Historical growth trend of 5%, but likely slower (2–3%) (9–13 mil) replacements the past few years due to LPG market disruptions and and new sales lower subsidies, likely to accelerate as LPG prices fall Kerosene 12–18 mil Replacements –2% to 1% • Largely a replacement market, as kerosene use is (?) sales at ~4–6 mil shrinking in relative (and possibly absolute) terms across SSA Electricity 10–15 mil 3–4.5 million 4% • Replacement market driven by relatively short shelf (11–16 mil) replacements life of electric stoves; at very top of market, adoption and new sales growing for electric induction ovens Concentrated in South Africa and Ethiopia • Biogas 10–15k 10k–15k 10–30% • Historical growth rate on biogas plant construction (40k) in Africa extremely slow, but increased progress seen with Africa Biogas Partnership Programme • Market heavily dependent on subsidies for progress, so trajectory after end of currently earmarked funds is unclear Solar 50–75k 5–10k per year 2–10% • Slow growth thus far for leading NGOs and private- sector entrepreneurs in the Africa solar sector Biofuels 100–150k >50–100k per 20–40% • Ethanol and ethanol gel fuels biggest focus of activity (300–350k) year and sales, but commercial ethanol fuel models still in early stages, with a range of distribution challenges Alternative fuel sources (e.g., jatropha, methanol) have • not gained traction Source: Africa stove penetration database; data points on sales trajectories for two-dozen stove programs and private-sector entrepreneurs; interviews; desk research; Dalberg analysis. 62 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Clean modern fuels: As noted in the fuel demand section earlier in this report, clean modern fuels are slowly becoming more available (Figure 32) and are stimulating stove sales as middle-class incomes rise, particularly in the LPG and electric stove markets. Extrapolating from long-term fuel-use trends, LPG and electric stove numbers are growing by 5% annually from the 2010 baseline, while the number of kerosene stove users will likely continue the slow decline experienced over the past few years, due to the suspension of kerosene subsidies in key markets, such as Nigeria.152 Figure 32: Domestic LPG consumption for top SSA LPG markets Domestic LPG consumption (household, commercial, and industrial, million tons) 20002012 Annual % growth 1,606 57% 1,446 368 South Africa 3% 365 240* Sudan 18% 1,001 218 125 Nigeria 21% 245 76 123 Ghana 12% 694 105 173 121 Côte d’Ivoire 7% 103 257 17 117 Angola 8% 57 108 60 112 Senegal 1% 13 33 86 110 32 100 Kenya 16% 56 131 82 44 55 55 Mauritius 3% 99 43 26 45 46 Cameroon 3% 16 38 43 31 120 180 198* SSA other 8% 75 2000 2005 2010 2012 Sources: UN statistical abstracts; press reports; DataMonitor—Statistical Review of LP Gas; Dalberg analysis. Contrary to the regional trend, LPG adoption has slowed in some markets, due to subsidy reductions and infrastructure bottlenecks that have led to fuel shortages and price spikes.153 More recently, LPG adoption appears to be increasing rapidly in several markets like Kenya as consumers react to falling LPG prices against the background of continuing high charcoal prices in urban areas. Even faster growth of this market seems possible because the Global LPG Partnership—a public–private alliance with an ambitious target of transitioning © Global LPG Partnership/2014 © Global LPG Partnership/2014 63 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report 50 million developing-world consumers to LPG by 2018—is launching an intensive set of market development activities in several SSA countries, starting with Cameroon, Ghana, and Kenya. Markets for Renewable Cooking Fuel Markets for renewable cooking fuel in Africa are at a very early stage of development. The market penetration of biogas digesters has grown from a few thousand units across the region five years ago to 40,000 units by early 2014, driven largely by the efforts of the Africa Biogas Partnership Programme (ABPP) in Burkina Faso, Ethiopia, Kenya, Tanzania, and Uganda. Progress has been slower than initially expected, but the program has recently secured a new round of funding and is planning to launch a second phase of work (2014–17) to promote the construction of an additional 100,000 biogas units in its core countries and in additional geographies, such as Benin, Cameroon, Rwanda, Zambia, and Zimbabwe. The liquid and gel biofuel stove market has seen some significant investments in recent years. Despite the uptake of about 350,000 ethanol stoves across SSA by the end of 2013—largely in Ethiopia, Ghana, Kenya, Malawi, Mozambique, Nigeria, and South Africa—the track record of commercial efforts has been mixed. One of the best-funded ventures in this sector, CleanStar Novozymes Mozambique, was recently liquidated by its investors. Despite selling more than 30,000 stoves, the company was unable to achieve the stove penetration required to make the venture financially viable for its investors, given high marketing costs and the extensive (40–50%) subsidies embedded in the sales price of the Domestic CookClean ethanol stove used in that effort. The venture, under the NDZiLO brand, is still continuing on the ground, with some success with a new business model and under local ownership. CleanStar is also continuing its activities in the sector, with a new ethanol venture in pilot stage and is slated for a launch in Kenya in 2015. Other ethanol gel businesses, such as BioHeat/BioCorp (South Africa), Consumer Choice Limited (Kenya), and ThermoSafe (Nigeria), are seeing steady growth. Some, such as Nigeria-based Green Energy & Biofuels (“KIKE Green Cook” stove), already report reaching significant scale, with up to 200,000 stoves reported in multiple West African countries in just three years of operations. The market for briquette and pellet fuels, although at an early stage, is attracting investment, with new consumer-focused pelletizing and briquetting factories launched in Côte d’Ivoire, Ethiopia, The Gambia, Ghana, Nigeria, Rwanda, Senegal, Tanzania, Uganda, Zambia, and elsewhere (Figure 33). This is a major step forward alongside longstanding artisanal briquette manufacturing initiatives promoted by NGOs. The African solar cooker market is growing, but slowly. Despite efforts by a number of dedicated NGOs and entrepreneurs, it has seen few major new projects in recent years in terms of private-sector or donor investments. Cumulatively, the various NGOs (e.g., Solar Cookers International) and private-sector players in this sector are deploying fewer than 10,000 new solar cooker units annually across the region. Finally, retained-heat cooking, while still a small niche, has grown with the adoption of the WonderBag in South Africa and ambitious plans by Native Balance, the WonderBag’s manufacturer and promoter, to expand distribution across Africa in the coming five years. Improved and Clean Biomass Cookstoves (ICS and ACS) The African improved and clean biomass cooking market is still dominated by legacy stoves and basic ICS, but sales of more efficient ICS are growing quickly, and much cleaner (ACS) biomass stoves are moving toward broader rollout. A review of the ICS market’s composition over the past three years illustrates the region’s changing biomass stove landscape (Figure 34). 64 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Figure 33: Africa briquette and pellet fuel business for household cooking Bezaleel Sources: Press searches, interviews, Dalberg analysis. Figure 34: Africa ICS and ACS biomass stove mix (2011–2013) Directional estimate of stoves in market (millions) 2011 2013 2729 ACS (Tier 34) 550k 0.1 ACS (Tier 34) 40100k Fan gasifier 0 Fan gasifier 0.02 Natural-draft gasifier <0.05 8 Natural-draft gasifier 0.020.08 2022 Intermediate ICS (Tier 23) 4 mil <0.05 Intermediate ICS (Tier 23) 8 mil Built-in wood rocket 1.7 4 Built-in wood rocket 3.0 Rocket injera stove 1.8 Rocket injera stove 2.5 Portable wood rocket 0.5 Portable wood rocket 1.0 High-end charcoal stove 0.1 High-end charcoal stove 0.5 1113 810 Basic ICS (Tier 12) 8-10 mil Basic ICS (Tier 12) 1114 mil Basic charcoal ICS 57 Basic charcoal ICS 79 Charcoal mid-range ICS 0.3 Charcoal mid-range ICS 0.6 Basic wood ICS 2.53 Basic wood ICS 34 Legacy stoves (Tier 01) 8 mil 8 7.5 Legacy stoves (Tier 01) 7.5 mil Legacy or traditional w/chimney 6.3 Legacy or traditional w/chimney 5.7 Enclosed mud/clay unvented 1.8 Enclosed mud/clay unvented 1.9 2011 2013 Note: 2011 mix based on country-level database by stove type; 2013 mix derived by adding known (self-reported) sales, rest forecasted based on historical growth. Sources: National energy surveys; self-reported stove sales data for 100+ organizations; interviews; Global Alliance for Clean Cookstoves market assesments and member surveys; Dalberg analysis. 65 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Legacy stoves and basic ICS account for more than 80% of all improved and clean biomass stoves in SSA. Legacy stoves (~8 million) are a difficult market segment to quantify. The category includes mud chimney stoves (more than 6 million units), such as the vented mud stoves in Malawi; Malagasy chimney wood stoves in Madagascar; and enclosed low-efficiency nonchimney mud stoves of the type that have been commonly distributed in Ethiopia (less than 2 million).156 Within the basic ICS segment (8–10 million), the most common technology is the Kenya Ceramic Jiko and analogous charcoal ICS, which is manufactured via artisanal and semi-industrial providers across the continent.157 Basic wood ICS158 were a smaller but, at 2.5–3 million units, still substantial segment in 2011. Both of these segments received strong donor support through such initiatives as GiZ ProBEC, the EnDev program, the activities of the United Nations High Commissioner for Refugees (UNHCR) and the United Nations Development Programme (UNDP), and a range of stove-dissemination projects led by NGOs, such as Practical Action, Enterprise Works/ Relief International, Mercy Corps, Peace Corps, Care International, Concern Universal, and World Vision. The intermediate ICS (4.4 million) segment in 2011 consisted of portable rocket-style stoves designed for charcoal (less than 0.1 million) and wood (0.5 million) fuels and much larger subsegments of built-in rocket stoves, such as the Tanzanian Okoa, the Ugandan Rocket Lorena, the Kenyan brick rocket, and the Malawi TLC rocket (1.7 million), as well as specialized rocket injera stoves (1.8 million), such as the Ethiopian Mirt and the Eritrean Adhanet Magogo. Finally, ACS were practically nonexistent in Africa in 2010–11, at a maximum numbering in the tens of thousands across various pilot sites around the SSA region. Comparing the 2011 landscape with the situation in early 2014, it is clear that the market has undergone some significant shifts—an evolution that points to important trends for the coming years. Legacy stove penetration has continued its stagnation or decline (depending on country), as households increasingly abandon old stoves that are no longer being supported by government and NGO efforts.159 Basic charcoal ICS penetration is growing at a rapid pace, as semi-industrial manufacturers, NGO–intermediated artisan collectives, and individual artisanal entrepreneurs continue to scale up production to meet the demand caused by growing urbanization, accelerating charcoal use, and quickly rising charcoal prices.160 Basic wood ICS adoption has grown more slowly, with the fastest growth tracked as part of ICS promotion programs. One example of the latter is the rise of basic wood ICS penetration in urban Burkina Faso households to 10% from nearly zero over the past few years as part of the FAFASO program.161 In absolute terms, the most dramatic increase in rocket stove sales and dissemination is illustrated by the doubling of the penetration rate of intermediate (i.e., rocket stove) ICS technologies in Africa, from roughly 4 million in 2011 to 8 million by the end of 2013.162 There are several causes for this acceleration: the maturation of international rocket stove manufacturers in the past few years as they perfect their products and extend their distribution networks; the on-shoring of production in Africa during 2012–14 by major players in the rocket stove segment, such as Envirofit, EcoZoom, and BURN Manufacturing; the growing scale of domestic semi- industrial firms, such as Ugastove in Uganda and Toyola in Tanzania (both with small but growing wood rocket stove businesses); the shift to rocket stove promotion by national programs in some geographies; and the rapid growth of carbon-financed projects across the region in 2012 and 2013, which significantly enhanced profits for distributors of wood rocket stoves. The growth in rocket stove sales is expected to continue, given the major investments in manufacturing scale by several rocket ICS producers in 2013–14;163 the growing portfolio of rocket stove technologies offered by the largest carbon program developers, such as Impact Carbon; and the explicit new commitments to rocket stoves (both funded and still seeking funding) by national programs—such as Rwanda’s partnership with Del Agua Health and EcoZoom to distribute 600,000 rocket stoves to poor households across the country over an 18-month period starting in 2014.164 Finally, for ACS solutions, while it is premature to talk about distribution or sales growth trends, given the early stage of the marketing efforts of the key players, the number of stoves on the market has increased to up to 100,000 stoves, and a further accelerated pace of distribution is anticipated as ACS manufacturers and ACS- focused pellet fuel distribution businesses (such as Inyenyeri in Rwanda and Emerging Cooking Solutions in Zambia) scale up operations in 2014 and 2015. 66 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Trends in Stove Distribution The distribution of clean and improved cooking solutions is highly uneven across SSA, skewing heavily to urban areas, charcoal users, and a handful of countries with more developed stove and fuel markets. The good news of fast-growing access to ICS and other clean cooking solutions in Africa appears less rosy when one considers the highly inequitable patterns of access. Considered in terms of the urban/rural split of penetration and sales, access to clean and improved stoves is significantly higher in urban areas than in rural Africa. Excluding legacy stoves, nearly half of urban Africans own some form of clean or improved stove, compared with less than 10% of the rural population (Figure 35). Greater urban ICS adoption is also reflected in the much greater SSA penetration of ICS among charcoal (23%) rather than wood (13%) users, since charcoal is the quintessential urban solid fuel. The trend is most notable in such well-developed ICS markets as Kenya, where such basic charcoal ICS as the Kenya Ceramic Jiko have now become the new baseline technology (used by 70% of overall charcoal users and 80–90% of charcoal users in such cities as Nairobi and Mombasa), but wood ICS penetration among firewood users is significantly lower (less than 10% in 2004, up to 30% in 2010) (Figure 35).165 Figure 35: ICS penetration among users of wood and charcoal stoves Share of solid-fuel households with ICS (%) Share of solid-fuel households with ICS (%) SSA (2010) Kenya (2004) Kenya (2010) SSA (2010) Kenya (2004) Kenya (2010) Traditional stove ICS Traditional stove ICS 80 80 40 23 30 13 10 40 23 30 13 Wood Charcoal 10 Wood Charcoal Wood Charcoal Wood Source: Wood Charcoaldatabase; manufacturer Africa ICS penetration Charcoal and expert interviews; Wood stove program data (ISAK); Charcoal Dalberg analysis. Source: Africa ICS penetration database; manufacturer and expert interviews; stove program data (ISAK); Dalberg analysis. The uneven pattern of distribution is also obvious for stoves running on modern fuels. National household survey data show that just five countries across SSA contain 56% of LPG stove users, 74% of kerosene stove users, and 90% of electric stove users.166 These disparities, when both “clean” and “improved” cooking solutions are combined, translate into very uneven coverage across Africa. Penetration of clean and improved solutions stands above the 50% mark in only 10 SSA geographies, typically represented by relatively more developed nations, such as Botswana, Kenya, Senegal, and South Africa. The combined share of households using clean and improved stoves in these 10 countries is nearly half of all improved and clean stoves in Africa. In a full quarter of SSA countries, less than 10% of the population used anything other than traditional fuels and stoves for cooking in 2010–11 (Figure 36). 67 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Figure 36: Penetration of modern fuels and improved cookstoves, by SSA country (2010) Clean and improved stove share of SSA population (2010) Traditional stove/open fire Nonlegacy ICS (basic, intermediate, ACS) Legacy stove Modern-fuel penetration 100% 80% 60% 40% 20% 0 Cape Verde South Africa Botswana Gabon Senegal Swaziland Rwanda Guinea-Bissau Angola Kenya Chad Namibia Zimbabwe Eritrea Ethiopia Lesotho Nigeria Uganda Cameroon Congo Rep. Comoros Ghana Côte D’Ivoire Benin Zambia Madagascar Tanzania Malawi Niger Burkina Faso Mali DRC Sudan Somalia CAR Togo Mozambique Sierra Leone Burundi Guinea Liberia underestimate the population using traditional stoves in countries with large modern-fuel populations (e.g., Senegal, Kenya) due to extensive biomass fuel use by LPG users. Sources: Country-level ICS penetration database, based on interviews and press searches; WHO global fuels database; Dalberg analysis. 68 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Structure of the Cookstoves Manufacturing Sector While the African cookstoves sector is currently dominated by artisanally produced cookstoves, industrial and semi-industrial manufacturers are rapidly gaining in scale and market share. Improved and clean biomass cookstoves can be categorized into three methods of production: artisanal, semi-industrial, and industrial (Figure 37). Figure 37: Clean and improved cookstove production models in Africa Increasing mechanization + centralization of production + quality control Artisanal Semi-industrial Industrial Producer Central assembly Local low-tech Local high- Global networks5 & of artisanal integrated tech integrated mass scale individual artisans components production production Minimal or no Integrated assembly Basic industrial or Moderate to High-tech, mass- automation; workshop, central semi-industrial tools high levels of scale integrated individual artisans procurement, (folding, drilling, automation; high manufacturing with and artisan central QC, and welding); some quality components; precision tools, collectives, typically common brand automation; salaried imported precision quality materials, with facilitating but very little staff; local to parts; strong QC world-class QC, institution for automation; premium materials; often linked to extensive in-house training, and extensive some do flat pack global “parent” design and R&D QC; may share outsourcing to assemblers; mid- manufacturers capabilities workshop space external artisans; range QC and common tools and use of local components (1) Africa stoves manufactured in Africa (Lesotho) plant by ACE under license from Philips; global ND stove production currently suspended; (2) EcoZoom scaling up Nairobi manufacturing capacity in 2014; (3) Envirofit has global and Africa (Nairobi) manufacturing capabilities; (4) design/R&D within separate Burn Design team in US; (5) most are NGOs supporting individual artisans and artisan collectives, not social enterprises in their own right. Source: Interviews; press searches; Dalberg analysis. Terms and attributes describing industrial production models are often used inconsistently. For the purpose of this report, industrial production is defined as scalable manufacturing that relies on a large degree of automation, precision tools, sophisticated materials, highly skilled and trained workers, and rigorous quality control. Industrial manufacturers are also likely to have significant in-house R&D capabilities, though in the case 69 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report of Africa-based production and assembly, the R&D capacity may often reside outside the continent in such locations as Europe, the United States, and Asia. Artisanal production is manual, with self-trained or minimally trained artisans (often individual micro- entrepreneurs in the informal sector), indigenous materials, simple designs, and much weaker quality control measures. In their most sophisticated form, intermediated artisanal models (e.g., EnterpriseWorks and Tatedo) rely on decentralized production models (i.e., individual artisans), but with an overlay of centralized procurement, quality control, and sales provided by an NGO or social enterprise. Semi-industrial production is the most difficult mode to define. It ranges from relatively low-skilled assembly of prefabricated components to domestic manufacturing with moderate levels of automation. Tools used for semi- industrial production will typically include flanging, bending, and rounding machines for metal works; folding, drilling, and welding sets for stove assembly; and extruders and improved kilns for liner production. Unlike the industrial assembly-line process, semi-industrial manufacturing will typically have a workshop workflow with multiple artisans/workers working in parallel on individual stove construction and finishing. Figure 38 reviews key features of each of these modes of production. Figure 38: ICS and renewable stove production models range from industrial, to semi-industrial, to artisanal Increasing mechanization, centralization, and quality control Artisanal Semi-industrial Industrial >6–10 million units annually >400,000 units annually 350,000 units annually 10k–15k artisans/masons 25–40 firms <10 firms, +5 in last 2–3 years 100–5,000 units per producer/ 2k–100k units per producer/year 20k–150k units per producer/year year US$5–20 per stove US$20–100 per stove US$2–20 per stove • Traditional focus on basic • Focus on higher-end charcoal • Focus on KCJ-type efficient charcoal ICS and wood ICS, wood rocket stoves, and technologies, clay stoves, metal stoves; several have added gasifiers stoves, and home installation of wood rocket stoves to portfolio • Small sector, many at early stage fixed or semi-portable rocket- • Several (nonfan) gasifier entrants of commercialization style wood stoves in 2013–14 • Significant new investment in • Quality controls weak or absent • Manufactured using labor- scale-up by investors and/or in some markets intensive low-tech industrial or clean development mechanism • Many stoves sold as part of workshop processes (CDM) programs in 2011–14 integrated government/donor • Smaller players often have heavy • Several new manufacturing/ programs for artisan training donor/government support assembly facilities in Africa, but and market support most industrial stoves in market still designed in Europe/U.S. and manufactured in China Sources: Interviews; press searches; Dalberg analysis. Although each mode of production has its own sets of challenges, there are common themes. These include the growth of materials and labor costs affecting overall product affordability, the difficulty and cost of distributing stoves to the last mile, and—though the size and nature of the financing needs differ dramatically by segment—a lack of access to capital markets. Artisanal and small-scale semi-industrial players, in particular, contend with low margins, rising materials costs (particularly for metal components), low managerial and business planning capacity, and lack of working capital financing. Most critically, there are also significant quality control issues, which include the high cost and logistical challenges of accessing stove-testing services, and the limited technical ability of producers to ensure the quality of their products as they increase production.167 70 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report The quality control issue—combined with the growing economic pressures on small artisans and artisan collectives, and, historically, a lack of standards in African cookstove markets—has led to widespread quality and market spoilage issues. Many artisanally produced stoves in the field suffer from significant performance and quality challenges, including poor durability (e.g., short 3–12-month shelf lives before cracking); poor safety (e.g., they flip over easily, causing burns); and weak standardization of materials and designs, leading to fuel-efficiency levels that are far below potential.168 Semi-industrial manufacturers, which are typically relatively sizable family businesses, share some of the challenges of artisanal markets, but have specific issues, which include limited managerial and business planning capacity to scale beyond starting models, pressure on both labor and materials costs, and very poor access to financing due to their lack of formal business banking relationships and traditional collateral. For industrial manufacturers, in contrast, the biggest challenges are the high cost of materials and production relative to highly income-constrained consumers; high import duties and taxes for bringing imported stoves and components into most African geographies (in some countries, end users face a 40–60% mark-up in stove prices when all taxes and fees are accounted for); and the cost and complexity of building large-scale distribution channels (or tapping into existing channels) to reach target consumers. The composition of the market is changing quickly across these three production approaches. Excluding legacy cookstoves, which are typically built by the users themselves, about 90% of biomass ICS and ACS sold in Africa annually have been produced by artisanal methods in local workshops or built on location by trained masons. Semi-industrial and industrial stoves account for roughly 5% of annual production and sales each. The sales mix across the three production methods is changing quickly. Manufacturer and stove program data for Africa suggest that industrial and semi-industrial stove enterprises and programs have had much more rapid annual sales growth (35–200%) relative to the annual sales growth trend of 10–25% for the artisanal sector over the past five years. Factoring in replacement sales, these growth trends suggest a significant expansion of improved industrial and semi-industrial stove manufacturing capacity in Africa over the past 5–10 years, albeit from a very low base. Such growth of semi-industrial and industrial manufacturing share is encouraging given the relatively higher- build quality levels of such cookstoves. Projecting these trends forward, even with very conservative growth assumptions, points to a rebalancing of the market toward industrial and semi-industrial solutions (for instance, 20–30% of annual biomass stove sales in 5 years versus 5–10% today). Irrespective of such rebalancing, after decades of basic ICS technology promotion by donors and NGOs, the artisanal sector in Africa is large and, in the case of such technologies as the Kenya Ceramic Jiko, predominantly self-sustaining. There are commercially driven artisanal production sites across the region, and particularly large artisanal production clusters exist in such countries as Ethiopia, Ghana, Kenya, Senegal, Tanzania, and Uganda (Figure 39). In contrast, the promise of the industrial and semi-industrial production revolution in cookstoves manufacturing is reflected in the growing universe of such manufacturers across the region: more than 40 such companies are now manufacturing or assembling their cookstoves across a dozen countries (see partial list in Figure 40). Half of these companies started their Africa operations or entered the cookstoves market from other lines of business during the past five years. Others—such as CooksWell/Museki Enterprises in Kenya, Toyola in Ghana, and Ugastove in Uganda—are veterans of the cookstove trade, with roots in the NGO- and government-led basic ICS promotion efforts of the 1990s. Currently, most industrial manufacturers of African improved and clean cooking appliances (ICS, ACS, and stoves running on modern or renewable fuels) are clustered in Kenya and South Africa. Semi-industrial ICS manufacturers, meanwhile, are present in two-dozen countries, chiefly Ethiopia, Ghana, Kenya, Tanzania, and Uganda (Figure 40). Francophone Africa, Burkina Faso, the Democratic Republic of the Congo (DRC), Mali, and Senegal have sizable artisanal and, in some cases, semi-industrial manufacturing hubs, but the density of private-sector enterprise is substantially lower than in East Africa, and many players that do exist are still entirely dependent on their affiliation with donor and national government programs. 71 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Figure 39: Distribution of Kenya Ceramic Jiko (KCJ) and comparable solutions across Africa Households using ceramic jiko basic improved charcoal stoves and comparable models (2010) Households Households using ceramic using ceramic jiko jiko basic basic improved improved charcoal charcoal stoves stoves and and comparable comparable models (2010) models (2010) Country Local name Kenya Kenya Ceramic Jiko Rwanda Canamake Sudan Canun el Sarour Uganda Ceramic Sigiri/Usika Tanzania Jiko Bora Malawi KCJ/Ceramic Mbaula Ghana Gyapa Senegal Jambar/Diambar Original Kenyan Zambia Ziko Original Kenyan Ceramic Jiko Ceramic Jiko Ethiopia Original Kenyan Lakech Ceramic Jiko Mali Sewa Burundi KCJ Burkina Faso Diambar/Sewa >1 >1 million million DRC Butembo/KCJ >1 million Madagascar Fatana Mitsitsy >500K >500K >10K>500K Somalia Kenya Jiko >10K >10K Mauritania Sewa Source: Source: Press Press searches; searches; interviews; interviews; Karakezi Karakezi (2008); (2008); Dalberg Dalberg analysis. analysis. Source: Press searches; interviews; Karakezi (2008); Dalberg analysis. Figure 40: Select SSA industrial and semi-industrial clean and improved stove manufacturers (2014) Semi-industrial (assembly only) Semi-industrial (assembly only) Semi-industrial production Semi-industrial production Industrial production Semi-industrial (assembly only) Industrial production Semi-industrial production Industrial production Elohim Save 80 Potential Energy Elohim Save 80 Potential Energy GreenTech InStove GreenTech InStove Tizazu, Makobu Enterprises Elohim Save 80 Tizazu, Makobu Enterprises Potential Energy WorldStove GreenTech InStove WorldStove Katene KadjiKadji Katene Tizazu, Makobu Enterprises Ugastove, ILF, Awamu, AEF Ugastove, ILF, Awamu, AEF FOWE, FOWE, PEES, PEES, Sure Sure Energy, Energy, Rwashana Rwashana Soutra Forneau WorldStove Soutra Forneau Katene Kadji Sytap, Toyola Sytap, Toyola Ugastove, Musaki, Musaki, Keyo Keyo ILF, Awamu, Pottery, Pottery, AEF BakerStove BakerStove Toyola Toyola BURN BURNFOWE, PEES, Sure Manufacturing, Manufacturing, Energy, EcoZoom EcoZoom Rwashana Soutra Forneau CookClean Na Na Biso Biso Biso Biso CookClean Envirofit Envirofit Sytap, Toyola Man Man & Man & Man Musaki, Keyo Pottery, BakerStove Toyola Peko Peko Pe Pe M&R, SECCO, BURN Kiwia and Laustsen Manufacturing, EcoZoom M&R, SECCO, Kiwia and Laustsen CookClean Biso Na Biso Envirofit Man & Man Ken’s Steel Engineering Ken’s Steel Engineering Peko Pe M&R, SECCO, Kiwia and Laustsen TsoTso stove Cerâmica Térmica (?) TsoTso stove Cerâmica Térmica (?) Ken’s Steel Engineering New Dawn Engineering Rocket Works, Arivi, Natural Balance, TsoTsoDometic stove New Dawn Engineering Rocket Works, Arivi, Natural Balance, Dometic Cerâmica Térmica (?) ProtoEnergy, MbaulaGreen Philips/African Clean Energy ProtoEnergy, MbaulaGreen Philips/African Clean Energy Sources: Press searches; interviews; Dalberg analysis. New Dawn Engineering Rocket Works, Arivi, Natural Balance, Dometic Sources: Press searches; interviews; Dalberg analysis. ProtoEnergy, MbaulaGreen Philips/African Clean Energy Sources: Press searches; interviews; Dalberg analysis. 72 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Important industrial factory launches in the past two years include Envirofit’s new plant in Nairobi; the launch of the ACE factory in Lesotho (with a license to produce the Philips fan gasifier stove); the opening and scale- up of BURN Manufacturing’s Nairobi plant; EcoZoom’s ongoing efforts to onshore its assembly and production; BioCorp’s expansion of its ethanol stove manufacturing facilities in South Africa; and the launch of biogas plant manufacturing in Tanzania by SimGas in partnership with Silafrica Tanzania Ltd., the largest plastics manufacturer in East Africa. Notable recent launches of semi-industrial manufacturing facilities include the Baker Stove/Top Third Ventures factory in Kenya, the InStove manufacturing and assembly facility in Nigeria, the Biso Na Biso basic ICS factory in Kinshasa, and the Soutra Fourneau factory in Côte d’Ivoire. The estimated scale of investments in these and other comparable businesses is north of US$25 million over the past 3–4 years, with ambitious plans by several of these players and others to move up the local production value chain from assembly to more sophisticated component manufacturing and, within the next few years, expansion of manufacturing facilities or satellite assembly hubs to new geographies. Despite this progress, however, the industrial and semi-industrial sectors remain small and highly fragmented. Fewer than 10 industrial and semi-industrial players in the entire region have reached a scale of 50,000-unit annual sales; most produce between 2,000 and 15,000 units a year (Figure 41). Figure 41: The industrial and semi-industrial ICS sector is highly fragmented, with only a handful of players globally exceeding 50k in sales Self-reported 2013 Africa sales of improved and clean biomass cookstoves by industrial and semi-industrial manufacturers (n=35) 180,000 160,000 140,000 120,000 100,000 80,000 60,000 40,000 20,000 0 Sources: Dalberg database of 35 industrial and semi-industrial players in Africa; self-reported sales triangulated with public sources where possible. Furthermore, the number of models available from each industrial and semi-industrial manufacturer is limited, given the subregional or regional ambitions of many of these players and the diversity of the SSA consumer. As a point of comparison, the African solar lighting market features more than 100 solar lanterns and home system designs and more than 60 manufacturers focused on SSA.169 73 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Fuel Supply Trends On the fuel supply side, the market suffers from inefficient supply chains for biomass fuel, limited investment in alternative fuel production, and infrastructure bottlenecks for modern fuel energy. The fuel supply market in SSA is well established. Because woodfuel value chains employ more than 15 million people in Africa—7 million in charcoal alone— they are an important source of livelihoods for many of the poorest households across the region.170 At the same time, biomass value chains suffer from multiple market failures and regulatory challenges. These include lack of sustainable forestry management and related forestry and land rights issues, perverse incentives that impede sector reform (such as blanket charcoal-ban policies), high rates of sector informality (and related leakage of potential government tax revenues), and oligopolistic and inefficient market structures that lower overall sector efficiency and productivity (Figure 42). The World Bank’s research suggests that there is a major opportunity to improve the sustainability of biomass supply by addressing these challenges.171 Key steps encompass reforming and modernizing the fiscal and governance framework for Africa’s biomass, promoting sustainable forestry management, and aggressively promoting new, more efficient kiln technologies that reduce particulate emissions. Figure 42: Fuel supply: Challenges for the SSA charcoal supply Wood production Charcoal and harvest production Transport Wholesale Retail Challenges • Weak forestry • Waste and GHG • Oligopolistic • Significant • Unsustainable management from poor control and often informal livelihoods due to • Over-harvesting efficiency kilns limited value for payments capture of value of “free” resource (8-20% vs. 25-40% small transporters • Operate in by upstream in public forests potential) • Significant shadow economy intermediaries • Land rights issues • Low capacity informal payments and cause tax • Health hazards • Health hazards revenue loss Tanzania 33% 50% 17% Uganda 34% 33% 32% Senegal 15% 70% 15% Malawi 21-33% 33-50% 25-33% Kenya 20% 58% 22% Liberia 53% 24% 24% Cameroon 32% 40% 28% Cross-cutting challenges • Lack of sustainable forestry management, potentially leading to high rates of resource depletion and localized overharvesting • Criminalization / periodic charcoal bans mean that information on sector is limited and ability to influence sustainability is low • High rates of informality account for 30-50% of end-price instead of being captured as tax revenue • True economic costs of charcoal production not accounted for as wood seen as a “free” resource • Disproportionate value capture by large transporters and wholesalers at expense of producers and retailers, especially women Sources: Country woodfuel value chain reports; AFREA (2011); World Bank (2011b); Dalberg analysis. On the point of woodfuel governance reform, much-needed changes include formalizing the charcoal trade to bring it out of the shadows, promoting sustainable forest management schemes, and rolling out sustainable biomass certification programs. For achieving sustainable biomass production, key aspects that need to be considered are community-based forest management; clear rules governing sustainable lots; and the launch of innovative financing mechanisms, 74 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report such as United Nations Collaborative Programme on Reducing Emissions from Deforestation and Forest Degradation in Developing Countries (REDD+) and the Forest Investment Program (FIP).172 Community-based forest management (CBFM), in this context, means that rights and responsibilities associated with sustainable forest management are transferred to the local level, technical oversight and capacity building is provided by community authorities, and a share of taxes paid to the community or local government is earmarked and reinvested for forest maintenance and local community economic development. There is a growing list of successful donor-supported CBFM projects across Africa,173 but the scale of such initiatives and government engagement is still very limited when considered from a regional perspective. Finally, for the objective of improving kiln quality, major ideas include aggressively promoting new kiln technologies (Figure 43) by creating charcoal producer groups and facilitating access to small- and medium- sized enterprise (SME) financing and carbon finance streams for sustainable charcoal producers. Figure 43: Fuel supply market interventions example—improved charcoal kilns Traditional kilns Improved kilns Modern kilns Range of technologies from Artisanal and semi-industrial Industrial and semi-industrial earth mound kilns to crude kilns, including brick and retort and gasifier kilns brick kilns metal designs Efficiency 820% 1230% 2050% Emissions CO2: 450550 CO2: ~400 (in g per kg charcoal CH4: ~700 CH4: ~700 produced) CO: 450650 CO: ~160 Sources: World Bank (2011b); Sepp (2008); task team analysis. Needless to say, bringing about such deep systemic reforms is difficult. Most of these activities require significant funding, multi-year commitments, and experimentation in difficult institutional settings. The importance of engaging on the supply side does not, therefore, reduce the need to engage on woodfuel demand through improved cooking technologies. Other important supply-side fuel market opportunities include the potential for improving the supply of sustainable solid-fuel alternatives to traditional biomass, such as renewably manufactured briquette/pellet fuels (i.e., carbonized or noncharcoal fuels manufactured from renewable biomass, such as sustainably harvested woods and crop waste). As mentioned earlier in the report, while full of promise, the briquette/pellet market has seen insufficient focus and investment from the clean cooking community to date.174 In terms of modern and renewable fuels, there is an opportunity to significantly improve the uptake of both clean fuels, such as LPG, and renewable biofuel alternatives, such as ethanol, through large infrastructure investments and supporting regulations. Current efforts by the Global LPG Partnership are designed to encourage this systemic change by improving upstream and midstream LPG infrastructure through both large- scale investments (e.g., LPG storage facilities, cylinder manufacturing, cylinder-filling plants) and demand-side interventions (e.g., consumer financing and consumer education) to drive the demand for clean cookstoves and fuels for those consumers who can afford them. Cameroon, Ghana, Kenya, Nigeria, and Senegal are likely to be the major focal points for such efforts.175 75 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Cookstove Costs and Sector Economics Improved and clean cookstove fuel and appliance costs are high and unlikely to decline over time. Relative to the population’s purchasing power, most clean and highly improved cooking solutions in Africa feature both high upfront costs (US$20–100 for most technologies, US$500–1,500 for household biogas plants) and, in the case of many modern- and renewable-fuel stoves, significant annual fuel expenditures (Figure 44). That said, cookstove prices do vary across the continent. For locally manufactured stoves, this is because of differences in the price of labor and inputs; for imports, price differences arise from significant differences in taxes and tariffs and transport costs. On average, West Africa tends to have significantly higher prices than East Africa. Simple ceramic jiko-type cookstoves are 1.5–3 times more expensive in Ghana and Senegal than in Kenya, for example, and West African countries, such as Nigeria, also feature some of the continent’s highest effective tax and import duties for consumer durables. Across all stove types, manufacturing costs account for roughly half of the end-consumer price, followed by distribution costs (last-mile transport and retailer margins) and importation costs (Figures 45 and 46). Figure 44: Price and annual average cost for various cooking appliances Upfront price versus lifetime cost of ownership 400 Average annual cost of using cooking solution (US$)1 Low upfront cost, High upfront cost, High lifetime cost High lifetime cost 350 300 Electric Traditional stove (charcoal) 250 LPG stove 200 Basic charcoal stove Ethanol stove 150 Basic wood stove High-end charcoal ICS 100 Advanced ICS Wood rocket stove Built-in rocket stove 50 Biogas digester Low upfront cost, High upfront cost, (Price: US$950) Low lifetime cost Low lifetime cost 0 0 5 10 15 20 25 30 35 40 45 50 55 60 65 70 75 Average unsubsidized price of SSA cooking solutions (US$) Note: Some stoves have wide range of prices and annual costs. Consult appendix for full detail. Sources: Dalberg cookstove database; manufacturer interviews; press searches. 1. Includes fuel consumption equivalent to 320 MJ and stove price amortized over average stove life; for less commonly used fuels, such as electricity and LPG, average costs are calculated only from countries where usage of fuel is signi cant. 2. Assumes a life range of 10–20 years and includes US$10–20 annually for servicing/maintenance. 76 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Figure 45: Detailed cost distribution for artisanal, semi-industrial, and industrial models Semi-industrial Artisanal production Industrial production US$5 US$11 US$21 US$22 US$41 US$49 11% 14% 15% 18% 20% 26% 14% 10% 16% 9% 12% 23% 14% 6% 21% 14% 8% 15% 23% 18% 11% 11% 23% 14% 18% 13% 11% 5% 40% 30% 32% 27% 26% 32% Wood Efficient Wood Improved Wood Fan gasifier stove charcoal Rocket charcoal rocket (pellet) stove stove stove Distribution costs Taxes Manufacturing margin Raw materials Local transport Shipping and import duties Labor Note: Labor costs include manufacturing margin for basic artisanal stoves. Source: Sanitized self-reported manufacturer data; Dalberg analysis. High distribution costs may decline in urban areas and as the sector reaches greater scale, but—holding quality constant—there is no reason to expect major reductions in the manufactured cost component of ICS and modern-fuel stoves, because both labor and materials costs for consumer durables are increasing worldwide in real terms (i.e., faster than the rate of inflation).176 Cookstove costs are particularly sensitive to the price of steel, which has witnessed large price spikes in recent years in both primary and scrap markets and will remain a key input for quality cookstoves in the foreseeable future. The trend of rising prices distinguishes stove manufacturing from other off-grid energy products, such as solar lanterns and solar home systems, where prices have fallen dramatically over the years and will continue to decline, thanks to underlying technology improvements and trends in battery and lighting component markets. Increased domestic manufacturing and assembly in Africa are probably the best near-term lever for reducing cookstove costs. As shown in the following examples, this is because domestic production can reduce international transport and tariff costs, while at the same time fostering skills and technology transfer (Figure 46). However, mostly because of local infrastructure and capacity constraints, domestic production will not be feasible in all African markets. Although the low-cost, scaled manufacturing of more sophisticated stove solutions—such as fan gasifiers with thermoelectric generators, or TEGs—is still best effected in Asian manufacturing centers, the potential for basic and intermediate stove manufacturing in Africa is large. Product simplification is another promising lever for price reduction, particularly in the case of ND gasifier solutions which, with appropriate controls, can be manufactured locally using semi-industrial processes (Figure 47). 77 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Figure 46: Impact of portable rocket stove production in Africa Costs across stove distribution value chain per stove unit (US$) Costs across stove distribution value chain per stove unit (US$) WOOD ROCKET STOVE EXAMPLE1 WOOD ROCKET STOVE EXAMPLE1 Import of stoves manufactured in Asia Shift to Africa production Import of stoves manufactured in Asia Shift to Africa production 1025% higher Reduction could 1025% higher steel costs be lower if could Reduction parts steel costs be lower still if parts imported for +1-2 still imported Africa assemblyfor +1-2 -5 +1-2 Africa assembly +1-2 -5 7 -4 7 -4 -2 8 -2 8 Labor costs 32 Labor higher incosts some 5 32 higher in some African Local production 5 23 5 African geographies Local production often means 23 5 geographies means oftenlayers fewer of 7 fewer layers of intermediaries 7 intermediaries Materials Labor Overseas Import Africa Rural end- Materials Labor Overseas Import Wholesaler End- Materials and mfg. Labor transport/ Overseas duties/ Import distribution Africa consumer Rural end- Materials Labor transport duty Overseas Import margins/ consumer Wholesaler End- margin and mfg. Insurance transport/ VAT duties/ costs and consumer distribution price transport elimination duty fees margins/ price consumer margin Insurance VAT retailer costs and price elimination fees price margins retailer margins 1. Blended data from 3 4 manufacturers producing stoves in Asia and either considering or implementing shift of production to Africa . 1. Blended Sources: data from 3 interviews; Manufacturer 4 manufacturers public producing stoves value chain in Asia and data; Dalberg either considering or implementing shift of production to Africa . analysis. Sources: Manufacturer interviews; public value chain data; Dalberg analysis. Figure 47: Example of shifting natural-draft gasifier manufacturing to Africa semi-industrial production Costs across stove value chain (US$) Industrially mfg. ND TLUD imported from India ND TLUD manufactured semi-industrially in Uganda Overall performance: ISO Tier 23 Overall performance: ISO Tier 23 PM: 89 mg (range unknown)1 PM: 25180 mg1 CO: 8.1 g (range unknown) CO: 38 g Fuel savings vs. 3-stone fire: 40%+ Fuel savings vs. 3-stone fire: 45% Low VAT due to 6 low baseline product Easy-to-assemble cost; no import duties design for low- 10 skill labor Recycled 39 metal 10 3 5 16 13 8 Materials Labor Import Distribution Urban Materials Labor and Distribution Urban Africa and mfg. duties costs, Africa mfg. margin and VAT end-consumer margin and margins, end- price shipping and VAT consumer price 1. Approvecho testing for Africa-manufactured stove; self-reported results for India-manufactured stove; results from pyrolysis only, not burning resulting charcoal. Sources: Manufacturer interviews; public value chain data; Dalberg analysis. 78 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Although average margins are generally low across clean and improved cookstove enterprises, many manufacturers have already achieved, or are on a path to achieving, profitability. They have done this largely by drawing on carbon revenues and/or focusing on more profitable consumer segments, such as urban charcoal users, where sustainable economics are possible without public-sector and carbon-market support. Self-reported data from a dozen African companies across the clean and improved cooking value chain reveal that, although overall margins are low, best-in-class industrial and semi-industrial stove manufacturers can achieve a net income margin in the 15–25% range, while cookstove distributors—with their own sales forces and deep reach into the last mile—can likewise approach the 15–25% profit margin range, particularly if their businesses straddle both stove and fuel distribution (as is the case, for example, of integrated stove and pellet fuel distribution models). Local artisans typically see 5–12% margins, though higher margins are possible in new, less competitive stove markets. Semi-industrial manufacturers of basic and intermediate ICS consistently achieve profit margins of 10–15%; deeper margins are possible but difficult to achieve at scale for semi-industrial businesses once they fully penetrate their local base, as so much of their success is predicated on solutions well tailored to local markets and strong distribution relationships with local dealers and retailers. For local industrial manufacturers, while the trend may not apply more broadly, existing players are already achieving higher margins than international manufacturers bringing products into the same country. This is because local players are able to avoid taxes/import duties on their products and, all else being equal, are able to much more quickly scale up their business models at a lower cost base. Finally, for international manufacturers, there is a wide range of outcomes today, ranging from (1) money- losing models that are heavily reliant on both donor and carbon-market revenue streams to (2) much more commercially oriented models that are able to realize 10–15% profits, both by focusing on easier-to-reach and wealthier urban segments and by supplementing their income with carbon finance profits. At this early stage of market development, a significant portion of profits is reinvested into market expansion; however, based on current profit margins, it is clear that higher net incomes are possible in the future, when these businesses mature, with some targeting 20–25% gross earnings. Technology and Business Model Innovation Looking forward, the supply of clean and improved cooking solutions is being transformed via the emergence of promising new technologies and business models. In the market for nonbiomass modern and renewable cooking solutions, the most important innovations are focused on developing lower-cost cooking appliances and relevant business models. In the LPG market, to improve uptake by the urban poor and mass-market segments, firms have explored business models involving small, 3-kg cylinders with integrated burners, partial cylinder refill capability, and amortization of appliance costs built into fuel prices. Oando’s O-Gas and TechnoOil in Nigeria, EasyGas (Shell) EasyCooka in South Africa, National Oil and Total in Kenya, and Viva Gas’s Butagaz brand in Morocco are a few examples of African businesses promoting 3-kg cylinders to poorer consumer segments. The oldest use of such models is the Blip Banekh stove/2.75-kg cylinder combination in Senegal, promoted by Senegal’s butanization program since 1976. Gulf Energy’s Pima Gas in Kenya, aside from promoting very small (1-kg) cylinders, dispenses LPG from a mobile pump and allows for partial refills with an automatic switch-off mechanism once the desired amount has been filled. These approaches are innovative in the African context, but have precedents globally.177 While uptake of small cylinders has been relatively slow, ongoing experimentation with lower-cost LPG cylinders and stoves is an important sign of long-term cooking-sector commitment to expanding LPG access to poorer consumers. Liquid and gel biofuel promoters, in an effort to manage supply-chain risks and reduce fuel costs, have piloted new approaches to sustainable, decentralized fuel supply, such as micro-distilleries and feedstock outgrower programs. At the same time, they have aggressively promoted the adoption of biofuel stoves for urban kerosene and charcoal users. Building on its earlier African pilots, Project Gaia is continuing its micro-distillery and stove promotion efforts in such countries as Ethiopia and Nigeria.178 Thus far, biofuel production models have been attempted with limited success for such fuels as jatropha and methanol. In the ethanol cooking fuel market, there is increasing innovation in ethanol feedstock and production processes—most notably, the innovative approach from Green Energy & Biofuels in West Africa to produce ethanol from low-value biomass, such as water hyacinth and sawdust, and ongoing efforts by multiple ethanol producers to improve the quality of their 79 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report products. From a cooking appliance perspective, the ethanol cooking market is still dominated by just a few stove models, but ongoing research suggests that the efficiency and emissions performance of current ethanol and ethanol gel stoves can be improved significantly with moderate investments in stove design.180 The biogas digester sector is seeing the arrival of household biogas plants that are cheaper, modular, and easier to install. It is also benefiting from new distribution, promotion, and subsidy models that may accelerate biogas household adoption, though evidence from the field is still at an early stage, and the results such efforts as the Africa Biogas Partnership Programme have so far fallen below target. From a technology standpoint, the most exciting innovation in this sector is the small-scale biogas plants from SimGas, a Dutch firm operating in Kenya, Tanzania, and Zambia that is promoting mass-produced, low-cost, easy-to-install biogas digesters prefabricated from polyethelene.181 Other innovative, lower-cost, prefabricated digester technologies at various stages of commercialization include plastic bag digesters from EcoFys, piloted in South Africa and Tanzania,182 and plastic or fiberglass solutions from AGAMA Biogas in South Africa.183 Some of the most important technology and business-process innovations are taking place in the biomass cooking sector. New biomass cookstove technologies include better-performing and more durable basic ICS developed over years of trial and error by specialist NGOs and donors, such as the range of products distributed by GIZ/ProBEC and EnDev; and a growing number of intermediate ICS rocket stove models with advanced materials, precision engineering, and market-specific design adaptations (e.g., Envirofit, EcoZoom, and Prakti Design). Most critically, the biomass cookstove sector is seeing the emergence of semi-industrially and industrially produced natural- and fan-draft gasifier cookstoves (Figure 48) that hold the promise of truly transformative health and environmental benefits. Figure 48: Advanced biomass stove innovation—examples of ACS models for sale in Africa BioLite HomeStove Philips Smokeless Stove Jiko Bomba Qintas TLUD (Nigeria) Vesto Stove Awamu Troika Bingwa Peko Pe TLUD and TChar Mayon Turbo (Gambia) Sources: Roth (2014); press searches; interviews; Dalberg analysis. While none of the current gasifier stove models fully reaches the particulate emissions performance of modern fuels, the best-performing fan gasifiers, particularly in combination with high-quality pellet fuels, already achieve IWA Tier 4 for efficiency and can come close to IWA Tier 4 indoor emission standards. Many of the stove designers interviewed for this report believe that a Tier 4 biomass gasifier stove, in terms of both efficiency and emissions, is technically feasible and—on the basis of current R&D efforts in the region— predict that several Tier 4 biomass stove models will be ready in prototype form in 2015. Such stoves will initially be highly expensive (US$100–200) due to a range of likely features, including the presence of multiple burners (i.e., to reduce the number of times the stove needs to be lit for each cooking session); the use of high-end 80 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report materials and precision engineering for the stove body and combustion chamber; and the need for a chimney to maximally reduce household PM levels. Although stoves at this level of cost will not be commercially viable for most consumers as an upfront lump-sum payment, the possibility of Tier 4 performance from biomass cooking is a potentially transformative development when seen in the light of pay-as-you-go business models, which can theoretically resolve affordability barriers for relatively expensive products. Another important technology development is the rise of electrically powered or electricity-generating biomass stoves. Stoves with built-in sources of electric power (e.g., electricity-generating stoves or stoves powered by external power sources, such as solar panels) have several potential advantages. First and foremost, they enable the fan functionality essential to reaching the very low emissions levels of the best-performing gasifier stoves. They improve the economic value to the end user by allowing for phone charging (which can cost more than US$0.25 per charge in many African markets), and potentially saving household lighting expenditures on inefficient and expensive fuels, such as kerosene, by powering light-emitting diode (LED) lights, as in the case of the new ACE-1 Ultra-Clean Biomass Cookstove.1 Furthermore, stoves with an electric power component offer the option of integrating low-cost, stove-use monitors (SUMs) or more sophisticated particle and temperature sensors (PATS) into the stove design. In the case of the BioLite stove, for example, SUMs enable data capture of time-stamped usage metrics that can be tracked over time, including frequency of stove use, duration of use, approximate firepower profiles, and charger usage.ii The use of more complex built-in particle sensors (US$12–20) can further allow the monitoring of a stove’s emission signatures in real time.3 The presence of a stove power source—in a functionality that has not yet been tapped—also creates the potential for integrating clean biomass cookstoves into remote-controlled utility business models. For example, this could involve embedding a low-cost mobile chip (i.e., Global System for Mobile Communications [GSM] module) into a stove, allowing for remote stove activation or deactivation. In combination with SUMs, GSM chip functionality theoretically allows for instantaneous remote data collection on millions of stove users—a boon for any large-scale stove carbon-finance program where stove-use monitoring is a requirement—the possibility of much deeper insights into consumer behavior, and potentially a tool for stove entrepreneurs to help adjust their strategy and tactics to maximize clean stove adoption. Within the general trend of biomass stoves with electric functionality, the most exciting development is the introduction of TEG technology, illustrated in greater detail in Figure 49. TEG stoves eliminate the need for replaceable batteries or such alternative stove power sources as solar panels. In Africa, the technology is currently only available in BioLite stoves, but the lineup of such products is expected to grow. Already, “generic,” lower-quality TEG fan-gasifier stoves are available from Chinese manufacturers, and a number of BioLite’s Africa- focused competitors have explored TEG functionality, though the ability of branded manufacturers to release new TEG products is constrained, given some of the patent protections regarding TEG use in stoves.187 Other important developments for electric fan-assisted stoves beyond TEG include the introduction of stoves with long-lived batteries and alternative charging options, such as solar panels (e.g., the ACE-1 stove), which allow for a broader array of functionality, such as using the stove as a device to power household lights; and the inclusion of GSM chips that allow for remote stove activation and monitoring. Several entrepreneurs are also exploring the potential of retrofitting existing African cookstoves (traditional or ICS) with TEG units to tap into the potential economic benefits (e.g., phone charging) of TEG functionality.188 In 2014, BioLite introduced a new product in the market with such functionality called the KettleCharge; using TEG principles, this product is an electricity-generating kettle that draws power from a variety of heat sources, such as open fires and stoves, to produce 10 watts of power. From a business model perspective, the most important innovation in the improved and clean biomass cooking sector is the emergence of integrated fuel/stove project designs. Developed by such companies as Inyenyeri in Rwanda, Emerging Cooking Solutions in Zambia, the African Briquet Factory in Ethiopia, Awamu in Uganda, and Greentech in The Gambia, this model has the potential to dramatically improve both manufacturer and end-user economics, while achieving high levels of health and environmental benefits. 81 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Figure 49: TEG technology—BioLite example Operating process Operating process BioLite HomeStove 1 Wood, pellets, or other biomass are burned as fuels Behind the design 2 Excess heat is converted into electricity by the TEG Thermoelectric Electricity is used to power a fan, which oxygenates generator (TEG) 3 the fire and increases burning efficiency Air Heat Excess electricity is used to power the stove-use 3 4 monitor and can be used to charge mobile phones 2 Fan or LED lights Electricity 4 USB port 1 Fan USB port Heat Air Electricity Overview Pros/Cons • Fan-gasifier stoves generate secondary draft of air through + Reduces fuel consumption by more than 50% compared an internal fan, which force feeds additional oxygen onto with open fire, and also cuts emissions by up to 95% the flame, eliminating smoke, and leading to the + Charges electronic devices, such as mobile phones and near-complete combustion of the fuel LED lights in under- or unelectrified regions • Thermoelectric-powered rocket stoves do not require an + Allows for more precise remote stove-use and external power source because they use a TEG to convert performance monitoring, and creates potential for remote heat from the fire into electricity activation and pay-as-you-go functionality • TEG technology enables the stove both to autonomously - Fans/electronic components increase price power an internal fan and to generate surplus electricity to - Components like TEG may reduce durability over the long charge mobile phones, LED lights, and potentially other term, though their track record to date is very strong devices (e.g., stove-use monitors, GSM chips) - Large amount of time taken to charge electrical appliances without additional power sources (e.g., solar panels) Sources: Press searches; interviews; Dahlberg analysis. Graphic courtesy of BioLite. Inyenyeri, for instance (Figure 50), operates more like a cooking-fuel utility company than a typical cookstove distribution venture. The company distributes high-performance Philips fan-gasifier ACS (US$70 wholesale price) to urban and rural households in Rwanda. The vast bulk of revenues comes from the sale of densified (compressed) biomass fuel pellets to urban customers, with stove-leasing fees (US$7 per stove annually in urban areas) and carbon credits contributing to a lesser degree. All household customers are offered a fuel- supply and stove-lease contract, in which Inyenyeri retains ownership of the stoves and is obligated to train the customer how to use them with fuel pellets. The company absorbs all future repair and maintenance costs, thus eliminating risks that might otherwise inhibit adoption. Rural households opt to sign a version of the contract, whereby they bring clean, dry biomass to regional “collection hubs” in exchange for a no-cost lease of stoves and fuel pellet supply, thus working for the clean benefits that they receive.190 Training in the use of a fan-gasifier stove with pellets is an intensive process— particularly as it pertains to how to use several stoves in a household to eliminate the charcoal fuel and charcoal jiko-type stoves that are common in urban Rwanda. Thus, it is essential to recreate the retail distribution ubiquity of charcoal down to the neighborhood street level and even into evening hours, as customers must be able to purchase pellets quickly to match the convenience of charcoal. Inyenyeri operates its own retail shops, which also serve as training sites. However, these are too few and are spaced too far apart to meet customer needs, so pellet distribution is expanding to include charcoal vendors, small shops, and umbrella street vendors working on a commission basis. The Inyenyeri model, which is now being replicated in different variations by half a dozen businesses across Africa and Asia, simultaneously addresses a number of problems. These include high upfront stove costs and liquidity constraints for the poor; lack of willingness to pay and experience with new technologies; household tendency to combine old cooking solutions with new ones (the Inyenyeri model distributes 2–3 stoves per 82 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Figure 50: Integrated fuel/stove model—the Inyenyeri example Key features of the Inyenyeri model Stove distribution Carbon revenues per ton of CO2 abated • Inyenyeri markets and distributes Philips/ACE HD4012 ACE/Philips stoves gasifier stoves (two per household) to displace Stove marketing harmful baseline cooking technologies Stove lease management • Rural households receive clean stoves for free in Stove usage Annual stove return for a contractual obligation to provide an contract usage fee ongoing supply of biomass feedstock, equivalent to amount they typically collect • Urban households receive stoves in return for a low annual usage fee (e.g., US$6–7 per stove) and an obligation to use Inyenyeri pellet fuel Rural household Urban household • Rural households deliver feedstock periodically to a network of rural hubs/collection centers where the fuel is pelletized using large-scale off-grid (self-powered) pelletizing plants 1 kg 3 kg • Rural households obtain free processed pellets from collection centers upon delivery of feedstock; urban households purchase pellet fuels from urban stores Periodic pellet 4 kg purchases • Inyenyeri continuously monitors stove uptake, stove quality, and fuel usage, offering stove Feedstock collection repairs/replacements when issues arise Pellet manufacturing Pellet distribution/sales • Inyenyeri receives supplementary carbon revenues Fuel distribution for CO2 abatement that are used as working capital for scale-up Sources: Global Alliance for Clean Cookstoves Rwanda Market Assessment (2013); Inyenyeri interviews; Dalberg analysis. household from the very beginning and, potentially, a multi-burner biomass gasifier stove in the future; and—via focus on the lucrative urban charcoal markets—lack of commercial sustainability. Perhaps the most noteworthy aspect of such business models is that the gross profit from pellet sales can pay for the capital cost of two or even three high-cost, high-performance stoves per household in 1–1.5 years. Another new development that is further out on the horizon is the potential to apply mobile pay-as-you-go models to cookstoves, including remote stove activation and monitoring. The major challenge of traditional pay-as-you-go models, particularly for stove businesses that have less proximity to the end customer, involves the transaction costs of extending credit to and collecting payments from end users. Although the market for TEG-enabled or battery-powered fan stoves is still embryonic, the rise of stove technologies with autonomous electric power sources (such as the BioLite and the new ACE 1 Ultra-Clean Biomass Cookstove) creates the possibility for mobile solutions to address the transaction cost issue and, at least theoretically, to launch cooking utility businesses. While the potential for success for such models is highly speculative, it is becoming clear that the mobile activation, monitoring, and payment technologies that are currently being applied to such off-grid BoP appliances as solar home systems could soon be piloted for cookstoves. The core idea of such concepts is to use mobile payments and remote appliance monitoring to manage long-term leasing or utility arrangements. Upon receipt of payment from the end user, the off-grid appliance can be activated for a discrete period of time (e.g., a week of cooking), at which point a new payment is required to avoid disactivation. One option for bringing such models to life—leveraging the technology of information and communications technology (ICT)-enabled energy-access companies, such as mKopa and Mobisol—could involve embedding a GSM module into a stove or a linked stove-activation controller. The stove utility manager could track the periodic mobile payments for stove use and enable the system to be locked remotely in case of overdue accounts—thus decreasing the risk of payment default. Another approach is to link the stove to an off-grid activation controller that lacks GSM capability, but can be activated through pre-set activation codes. 83 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report One example of such an approach from the solar lighting sector is Angaza Design’s Energy Hub system. After depositing funds into Angaza’s mobile money account, the end user receives a phone call from the automated energy hub system. Customers holds their phone near the Angaza activation unit in their home, allowing for audio-based transfer of data to the unit (to trigger activation) and audio-based transfer of usage and diagnostic data from the unit back to Angaza (Figure 51). Figure 51: Mobile-enabled, off-grid model for an energy utility—the Angaza example 3. Angaza PAYG system automatically initiates Audio-based call to customer's phone and activates energy data transfer device using audible tones Angaza Energy Hub PAYG Management System • Receives mobile money payment • Automatically initiates phone call to the customer’s phone • Transfers payment data embedded in 4. Energy unit activated audible tones to the unit • Receives and stores data from the unit to until next payment and 2. Money transferred unlock a proportional amount of energy sends customer specific to Angaza mobile output usage and diagnostic data money account back to Angaza via audio-based data transfer 1. Customers purchase “energy credit” to unlock their devices Features of Angaza’s Pay-As-You-Go Model • Low cost (US$2) • Fits customer's cash flow • Recurring revenue • Bi-directional communication: usage and diagnostic data are sent back to Angaza Note: PAYG = pay as you go. Source: Angaza Design (2014). The low cost of the Angaza household unit (US$2) suggests that this approach could be piloted in the cookstoves context as long as the stove has an autonomous power source, such as the TEG on such stoves as the BioLite. Aside from enabling pay-as-you-go models, the two-way flow of information in such systems as Mobisol, MKopa, and Angaza allows for usage tracking that helps companies with after-sales maintenance support, ongoing product improvement, and—important for the cookstove context—remote usage data capture for monitoring carbon finance compliance. 84 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Clean and Improved Cooking Distribution Models Market players use diverse distribution models, with no single channel offering the “key” to all SSA consumers, given the diversity of the market. SSA cookstove market players pursue a variety of distribution models, ranging from direct sales to third-party dealer-distributor networks, micro-franchise models, and institutional sales strategies (Figure 52). Figure 52: Emerging distribution channels for clean cookstoves Direct sales 3rd-party private Social sector Institutional bulk Carbon project dealer-distributors partners sales developers and retailers Sell direct to Sell to third-party Run sales and Bulk purchases Wholesale consumer via sales (e.g., fast-moving order fulfillment and redistribution distribution via staff, branded consumer goods) via microfinance by institutional carbon project commission- distributor networks institution (MFI)/ clients, such as relief developers who based agents, or or direct to dealers NGO workforces, agencies, schools, have access to proprietary store and retailers (large government and government proprietary sales network or small format) extension agents, programs forces or third- or social micro- party distribution franchise networks relationships (e.g., Living Goods) Sources: Press searches; interviews; Dalberg analysis. The vast majority of ICS have been distributed either via direct sales to consumers—a highly effective but resource-intensive option—or via third-party dealer distributor networks. Micro-franchising pilots are generally at an early stage. Institutional sales and social-sector partnership channels (i.e., distribution via partner NGOs) have likewise seen smaller volumes to date, but are an important channel for accessing the lowest-income and most excluded segments of the rural population. Given the complexity and fragmentation of the SSA market, many successful players tend to work across multiple sales channels or—if they have the local presence, relationships, and know-how—focus their energy on building out their own direct distribution strategies. Direct models are the preferred options for local semi-industrial and artisanal manufacturers that are closely integrated with their customers and are able to break down behavioral WTP barriers through intensive engagement. Toyola Energy in Ghana is a perfect example of this model. The Toyola sales staff provides stoves on credit to consumers and gives them time to learn about the technology, thereby reducing potential adoption barriers. The PERACOD project in Senegal similarly markets stoves to consumers via the bëccëk daily installment sales system, stretching out a typical charcoal stove payment over a period of 12 days. 85 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report The direct model is also pursued by large carbon project developers, such as UpEnergy and the Paradigm Project. These players have realized that reaching the last mile is a highly thought-out capability that international manufacturers are neither able nor willing to invest in sufficiently, even once the carbon-financing streams are secured. As a result, these players have deployed their own door-to-door sales forces (e.g., the Avon model) in order to drive stove adoption. Large industrial players, on the other hand, prefer indirect distribution models. They will typically distribute either through the existing infrastructure of ongoing carbon projects with their own distribution channels, or through other third-party distributors that can provide rapid access to the market (though at the cost of heavy markups). To date, the majority of stoves, and in particular artisanal stoves, are sold and distributed through direct channels (Figure 53), an approximate analysis in the absence of robust Africa-wide sales data. Manufacturer data available to the report team suggest, however, that products from industrial manufacturers are being channeled primarily through third-party dealer/distributor networks, which account for 50-90% of Africa sales for most players in this segment. Figure 53: Overview of Africa cookstove distribution models Distribution models Sales Pros Cons share Direct sales channels <80% • Offers a great deal of control • Costly without scale, which is difficult to to the producer achieve in large rural markets Third-party dealer- <10% • Leverages existing • Producers have minimal control and must distributor networks warehousing and salesforce compete with others in the same channel of an established partner • Limited by partners’ reach, which may not • Convenient and low-cost include remote or rural areas Micro-franchise networks <1% • Leverages on-the-ground • Producers lose some control networks of franchisees who • Franchisees’ sustainability unlikely with are likely familiar with local just cookstove sales; needs to be part of a market broader scheme to add sufficient value to franchise owners/micro-entrepreneurs Social-sector partners <5% • Leverages NGOs (MFIs) to • NGO may not be planning for scale and couple access to finance sustainability once program ends with strong reach into an • Lack of sales skills in NGO staff existing customer base • NGOs unwilling to take on reputational risks by associating themselves with experimental products Institutional sales <5% • Ease of sale for producer in • Producers have minimal control large quantities • Institutions do not have the reach for fast scale-up that stove entrepreneurs aspire to • Long and expensive sell cycles for most cookstove enterprises to engage with institutional buyers Note: Includes semi-industrial and artisanal stove; distribution mix for industrial stoves skews heavily to third-party distribution. Sources: Press searches; interviews; Dalberg analysis. 86 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report © World Bank/Klas Sander 87 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report 88 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report © World Bank/Klas Sander The Enabling Environment chapter 4 89 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report The Enabling Environment Having reviewed the supply and demand landscape for improved and clean stoves and fuels in SSA, we now turn to a review of the “enabling environment”—the ecosystem of institutions and policy initiatives, including funding, surrounding the sector. Overview of the Cooking Ecosystem in Sub-Saharan Africa The enabling ecosystem for clean and improved cooking solutions is evolving rapidly. The clean and improved cooking sector in SSA is a complex ecosystem in which hundreds of institutional and private-sector players focus on different, often overlapping market niches and interventions. Figure 54 illustrates the range of sector participants, with a focus on region-wide or subregional examples, but is not meant to be exhaustive.191 From a sector coordination standpoint, coordinating platforms and advocacy initiatives have contributed to improved sector transparency; increased collaboration across donors, governments, and the private sector; and the continued mobilization of funds and raising of global awareness for clean and improved cooking solutions. These initiatives include the Global Alliance for Clean Cookstoves (GACC) and associated subregional and country-level clean cooking associations (e.g., in Ghana, Kenya, and Nigeria); the United Nations’ (UN’s) Sustainable Energy for All (SE4All); the World Bank’s Africa Clean Cooking Energy Solutions (ACCES) initiative; new knowledge networks, such as HEDON; and specific technology and fuel champions with an Africa-wide mandate, such as the Global LPG Partnership, the Africa Biogas Partnership Programme (ABPP), and Project Gaia. Funding for cooking initiatives and interventions in SSA is growing steadily, with the most active region-wide donors being the governments of Germany, the Netherlands, the United Kingdom, and the United States via a range of programs and funding vehicles. Among multilateral institutions, the World Bank is the primary funder via ACCES, the Biomass Energy Initiative for Africa (BEIA), the Energy Sector Management Assistance Program (ESMAP) multi-donor trust, and a number of sector-lending operations with dedicated biomass energy and/or cookstove components. Drawing on funding from these donors and others, the most prominent international NGOs and implementation agencies in the Africa cooking sector include EnDev, the Global Villages Energy Partnership (Clough 2012), Mercy Corps, SNV, World Vision, Practical Action, EnterpriseWorks, and such UN implementing agencies as UNDP and UNHCR. Having significantly scaled up their capacity in the past 1–2 years with the help of the GACC and other donors, stove-testing centers have become important players in the regional ecosystem and are active in Ghana, Kenya, Nigeria, Senegal, South Africa, and Uganda. Providers of wholesale finance are also a dynamic subsector, with increasing numbers of impact investors and, most notably, carbon finance project developers emerging over the past 2–3 years. Finally, a growing number of research and advisory institutions are regularly contributing to Africa cooking-sector knowledge development. The most important, aside from the GACC, are the World Bank; GiZ; United States Agency for International Development (USAID);192 NGOs, such as GVEP, SNV, MercyCorps, and Practical Action; health researchers across several institutions globally, typically funded by the U.S. National Institutes of Health;193 and independent research organizations, most prominently the Stockholm Environment Institute (SEI). 90 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Technology associations/champions Program implementers/int’l NGOs Testing centers/service providers Donors and multi-donor programs Coordinating platforms Fuel & stove suppliers/distributors 91 National alliances/government leads Financiers/investors Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Research and advisory services Figure 54: Overview of the SSA landscape for clean and improved cooking stakeholders Note: List is not exhaustive, but is meant to illustrate the biggest and most active cooking-sector stakeholders across the SSA region. Africa Clean Cooking Energy Solutions Initiative The objective of the Africa Clean Cooking Energy Solutions (ACCES) initiative is to promote the enterprise-driven, large-scale adoption of clean cooking solutions throughout SSA, with the goal to reduce poverty, health-related risks, and adverse environmental impacts associated with traditional cooking technologies and practices. ACCES was established through a consultative approach to identify the main barriers that impede market-based development of the clean cooking sector in SSA. It builds on experiences and lessons learned from donor, government, public, and private investments in clean cooking solutions; the World Bank’s own operations; as well as the Lighting Africa off-grid lighting market-transformation program. ACCES supports World Bank project design and implementation by leveraging funding from project operations and by providing its own technical support in order to maximize the impact of clean cooking activities. It has designed a set of tools and mainstreaming approaches that reflect varying country priorities and sector policies to help build momentum and economies of scale needed for market transformation. It operates using the following three main lines of support: “Delivering Products”—facilitating the creation of catalytic linkages between industry leaders and distributors The implementation of country programs will include supporting commercial distribution models that are more likely to rapidly achieve economies of scale, strengthen the sustainability of the sector, and support the market-based approach of the initiative. Support will include: • Facilitation of manufacturer-distribution partnerships. • Design of distribution roadmaps and national rollout plans for cleaner stoves and fuels. • Design of “challenge funds” and incentive packages for development, implementation, and scale-up of distribution models. —establishing a comprehensive quality assurance and technical support (QA&TS) “Managing Quality”­ system The regional QA&TS program helps provide a level playing field for market competition and more coherent support aligned with ongoing global efforts for developing ISO standards and testing capacity in the sector in order to enhance product information and consumer confidence in quality products. To help steer clean cooking markets in ACCES countries toward higher-quality products that present a strong value proposition to consumers, the ACCES initiative has developed: • Baseline assessments of performance for the most prominent cooking technologies in its target countries. • Definition of quality and tools for assessing the adequacy of quality control measures for stove manufacturers, distributors, and testing centers. • Minimum performance thresholds for stove quality that vary in their level of ambition according to national and/or sectoral priorities and policy agendas, with the goal of supporting progressively higher-performing technologies over time. • Technical support to manufacturers for improving quality and performance. “Activating Customers”—engaging consumers through targeted commercial marketing and promotion campaigns This line of support will include a differentiated and narrowly targeted approach to enhancing consumer awareness through below-the-line marketing efforts for key consumer segments, as well as broader information campaigns, depending on country context. More specifically, support in this area may include: • Improving field-based evidence of adoption though country-specific reviews of consumer engagement efforts, identification of best practices, and key socioeconomic and contextual drivers. • Design of country-specific communication action plans and roll-out of high-impact marketing campaigns. • Development and field testing of sales-promotion and consumer-finance schemes. Source: World Bank ACCES team. 92 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Beyond the growing number and sophistication of regional cooking-sector stakeholders, various cross-cutting developments are trying to address systemic supply-side gaps. These developments include increasing industry convergence on ICS quality with the establishment of provisional IWA 11:2012 standards for ICS performance tiers and progress toward the adoption of ISO standards based on these guidelines;194 the evolution of new cookstove monitoring and performance-measurement techniques, such as growing use of SUMs to assess household-level performance;195 and the broader adoption of experimental and quasi-experimental techniques to assess stove impact and refine distribution and marketing approaches. On the policy side, there is increased government focus on regulating biomass fuel production196 and some movement on regulatory barriers, such as cookstove taxes and tariffs.197 Better market intelligence resulting from new investments in consumer and market research is also an important cross-cutting development.198 National Programs Another important cross-cutting trend is the continued growth of national programs promoting clean and improved cooking solutions across the region. The number of country-level African cookstove programs has grown significantly over the past few decades (Figure 55). Since 2010, half a dozen new programs have been launched with the impetus of the GACC and new efforts by leading cooking-sector donors, such as EnDev and the World Bank. Figure 55: Overview of SSA clean and improved national cookstove programs 1984 1994 2010 Number of countries with national-level programs: 12 18 21 Sources: Gi ords (2010); Dalberg analysis. African countries with large active national-level programs currently include Burkina Faso, Ethiopia, Malawi, Nigeria, Rwanda, Senegal, and Uganda. Some of these programs are in fact supranational, with international donors supporting a range of large-scale cookstove interventions across the continent. Older national cookstove programs in countries, such as Kenya and Tanzania, and regional programs, such as GIZ’s ProBEC, have already generated significant impacts and have often transitioned into market-based initiatives or have been handed off to NGOs and industry associations. Figure 56 provides an overview of the most active national programs; Figure 57 reviews the major regional and subregional programs, such as ACCES, EnDev, ProBEC, and the West African Clean Cooking Alliance (WACCA). 93 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Figure 56: Overview of SSA clean and improved national cookstove programs Country Status/target Lead organizations Key program features Ethiopia 25% penetration (>3 The Ministry of Water • Primary objective of current program (2012–15) million ICS in use) in and Energy Alternative is environmental impact (i.e., reduced forest 2013, primarily Mirt Energy Technology degradation and GHG emissions) through the injera stoves and Promotion and distribution of fuel-efficient wood stoves (both lakech charcoal stoves; Distribution basic ICS and intermediate ICS) with a focus on few high-efficiency Directorate (AETPD) rural areas; secondary objectives include job wood stoves; is the lead agency growth, public health, and rural development. 3.4% modern-fuel across all public- and • Program is core part of Ethiopia’s long-term penetration NGO-sector entities; Climate-Resilient Green Economy strategy and earlier rounds of builds on earlier phases of the national program Target: 9 million efforts were led by (2005–11), which focused on the creation of ICS in use by 2015 the Ministry of Water sustainable, efficient stove markets in urban and reaching 4.5 million and Energy, Rural peri-urban areas. rural households Energy Technology (~35% penetration), • Current program components include capacity Centers, and Ministry 31 million ICS (100% building for government institutions at all of Agriculture, with penetration) by 2030 levels; a productivity improvement program extensive GIZ support for stove producers with financing and technical assistance; and a stove promotion and distribution effort that involves stove subsidies for end users (up to 20%), stove distribution with the help of public health and agriculture extension agents, and awareness-raising campaigns. Rwanda >50% basic ICS The Energy, Water and • The Ministry of Health and Del Agua have penetration for wood Sanitation Authority reached an agreement with EcoZoom to and charcoal uses in (EWSA ) is the lead distribute 600,000 wood rocket stoves (EcoZoom 2013; 0.3% modern- on government Dura) to poor rural Rwandans by 2015; the fuel penetration cookstove program primary focus of the effort is on health, which implementation, the is unique in an SSA national program context; Target: 600,000 Rwanda Environment the program is not market based (i.e., stoves are rocket ICS in rural Management distributed to consumers free of cost). areas by 2015 (30% Authority (REMA) is • Government efforts on market promotion, penetration); the the lead on clean under EWSA leadership, are encouraging the national strategy development adoption of basic wood ICS in rural areas and targets 100% ICS mechanism (CDM) basic charcoal ICS in urban areas, with the most penetration by 2018 projects, and the recent campaigns in 2010–12; continuing SNV/ Ministry of Health EWSA partnership to promote Canamake and is the lead on the Canarumwe stoves; REMA is developing several Del Agua/EcoZoom stove CDM projects for Rwanda; the Rwanda project National Climate and Environment Fund is likely to be a key future player on R&D funding. Nigeria <0.2% biomass ICS Nigerian Alliance for • Nigeria’s NCP, launched in 2014, will apply a penetration, not Clean Cookstoves market-based approach to encourage state and counting unimproved (NACC)/International nonstate actors to build on the achievements chimney stoves; Centre for Energy, of the National Clean Cookstoves Scheme and 28% modern-fuel Environment, and other government initiatives to promote clean penetration in Development (ICEED) cooking in Nigeria. 2013 (~2% without is serving as the lead • Fuel interventions focus on clean fuels (LPG kerosene); 0.1% organization for the and ethanol) and green charcoal; the biomass ethanol stoves Nigeria Cookstove ICS effort is heavily focused on enabling rocket Program (NCP), with wood stove promotion (e.g., Save80, Envirofit). Target: 10 million ICS the support of the households by 2020 Federal Ministry (i.e., 25% penetration) 94 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Country Status/target Lead organizations Key program features of Environment and • Key program components include certification Nigerian Investment for quality cookstoves from ICEED, promotional Advisory Facility and awareness campaigns to drive adoption, operational subsidy system to stimulate stove replacement, verification processes for monitoring and evaluation, and support for local stove producers (technical and financial). Malawi <2% ICS penetration, The Ministry of • The National Cookstoves taskforce is a public– not including legacy Environment and private partnership entity launched in early 2013 stoves; 1.6% modern- Ministry of Energy to build on activities from 2005 to 2008. fuel penetration (co-chairs), Concern • Objectives include conducting a national International cookstoves market assessment, developing a Target: 2 million (secretariat to the national adoption strategy, preparing a national ICS and clean stove National Cookstoves communications/consumer education strategy, households by 2020 Taskforce), and EnDev providing producer commercialization support, (i.e., 50% penetration) promulgating national standards and standards monitoring mechanisms, and scaling up current cookstove and carbon credit activities. Uganda ~10% biomass ICS Uganda National • Starting in 2014, the newly established UNACC penetration by 2013, Alliance for Clean is the nonprofit national coordinating partner evenly split between Cookstoves and implementation agency with the mandate urban basic charcoal (UNACC), working of establishing an enabling environment for ICS and intermediate in coordination equitable universal access to clean cooking wood ICS (Rocket with the Ministry of solutions in Uganda by facilitating increased Lorena, Envirofit); Energy and Mineral innovation in design, testing, production, small ACS segment; Development (lead marketing, and use of clean cookstoves and 2.1% modern-fuel government agency); fuels; government policies and increasing public penetration (1.1% most active donors awareness; downstream and upstream access to kerosene, 0.6% LPG and NGOs include finance; and producer and distributor technical 0.6%) in 2011 GiZ, World Bank, capacity. EnDev, International • Key older programs include the Renewable Target: 5 million Lifeline Fund (ILF), and Energy and Energy Efficiency Programme households by 2020 Global Villages Energy (PREEEP) (2007–14), implemented by GiZ with (55% penetration) Partnership (GVEP) the objectives of increasing access to improved with “clean and efficient” cookstoves biomass energy technologies through the dissemination of household mud stoves, capacity building to private stove companies, and promotion of sustainable charcoal production; EnDev Uganda (2008–14), a multi- donor program to promote basic ICS and rocket ICS (Rocket Lorena) stove production and distribution and seen as a major success; GVEP’s Developing Energy Enterprises Program (DEEP) (2008–13), which focused on capacity building and market creation for artisanal biomass stove and fuel producers; Biomass Energy Initiative Africa (BEIA), a World Bank-funded project focused on market research and innovation efforts, such as the piloting of a locally manufactured TLUD gasifier. 95 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Country Status/target Lead organizations Key program features Senegal <280,000 basic The Ministry of Energy • PERACOD, a program for the promotion of charcoal and and Mines Is the lead sustainable energy, rural electrification, and wood ICS, 20,000 government agency sustainable supply of household fuels, is funded intermediate ICS for all clean and by BMZ and led by GIZ under the supervision in 2011, for total improved cooking of the Senegalese Ministry of Energy. It started ICS penetration of solution efforts; in 2004 and is due to end in 2015. Its objective ~30%; 33% modern- the Ministry is the is to contribute to a lasting improvement in fuel penetration in implementation access to rural energy services, with a focus on 2011; cumulative partner for PROGEDE renewable energy (such as home solar systems) penetration likely and is actively and sustainable household fuel supply. <50% due to involved in the -- More than 100,000 stoves in use by duplication (i.e., PERACOD/FASEN households by 2013 due to PROGEDE and >50% of urban ICS effort an additional target of 25,000–30,000 stoves households are to be distributed by 2015 with funding from primary LPG users) ProCEAO (Programme pour l’Energie de Target: 450,000 Cuisson Economique en Afrique de l’Ouest). ICS target under -- Initial focus on urban and peri-urban markets; PROGEDE; more recently reoriented to rural Senegal. 130,000–150,000 ICS -- Mid-term review in 2009–10 showed households target by significant overlap between owners of 2016 for PERACOD/ PROGEDE ICS and LPG users, reducing the FASEN; cumulative relative impact of PROGEDE on health and penetration target environment outcomes. is 60–70% clean • One of PROGEDE’s objectives is to increase the and improved stove availability of diversified household fuels and penetration stoves through community-based approaches. The program’s primary focus has been the creation of a sustainable charcoal cooking market in Senegal. PROGEDE is implemented by the Senegalese government (first phase 1999–2008) with funding from the International Development Association (World Bank), the Netherlands’ Directorate-General for International Cooperation, and the Global Environment Fund. Its second phase (2010–16) is being funded by the World Bank and the Nordic Development Fund. PROGEDE seeks to modernize the household cooking fuels and cookstove markets through the differentiation of a range of fuels, improvement of the supply chains, and support for appropriate energy regulations. Note: PROGEDE = the World Bank’s Sustainable and Participatory Energy Management Project. Sources: Press searches; GACC market assessment reports; Ethiopia Fuelwood-Efficient Stoves Investment Plan: 2012–2015 (2012), Project Document for National Clean Cookstoves Programme for Nigeria (2013); Malawi National Clean Cookstoves Taskforce launch documentation (2013); Dalberg analysis. 96 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Figure 57: Large regional cookstove programs in Africa Agency— Overview Geographic Focus within Funding source Africa results/ program focus the clean cooking targets sector World Bank (WB) The World Bank’s Sub-Saharan • Market Technical support Status: Working in Africa Clean ACCES initiative Africa intelligence funded by the several WB country Cooking Energy promotes the • Creation of Africa Renewable projects by Solutions (ACCES) enterprise- catalytic linkages Energy Access providing support driven, large- between Program and through analytical (2012—ongoing) scale adoption industry leaders implementation pieces, project of clean cooking and distributor funding leveraged design, increased solutions through the lending/grants, • Targeted efforts throughout SSA World Bank’s and setting up to engage energy investment implementation consumers in key projects in select arrangements; segments countries upon successful • Establishment completion of of a regional QA projects, looking and technical to scale across the support system regions Global GACC is the SSA focus • Market Range of donors Status: Local clean Alliance for Clean leading global countries intelligence in cooking alliances Cookstoves platform for in Phase 1: focus countries established in (GACC) clean cooking Ghana, Kenya, and additional key geographies; energy Nigeria, geographies market promotion with Uganda (e.g., Ethiopia, development regional Africa Rwanda, South activities launched activities Africa, Tanzania) Target: 100 million • Set-up of households national alliances globally with clean to coordinate cooking by 2020; local agenda >20 million from • Targeted Africa investments and market development activities Energizing EnDev seeks Benin, Burkina • Conducting Funded by the Status: 1.3 million Development to support Faso, Burundi, baseline surveys Dutch and German in Africa (out of Program (EnDev) energy-business Ethiopia, for technology governments, 3 million EnDev entrepreneurs Ghana, Kenya, adaptation; European Union stoves in use (2005–19) with knowledge Mozambique, training (EU), and Irish globally by end transfer, technical Rwanda, producers; Aid; since 2011 of 2011); >1.5 assistance, and Senegal, quality control also funded by million African capacity building Uganda and stove the Norwegian households marketing government reached by 2014 • In Africa, EnDev is promoting only non- subsidized stoves, hence targeting sustainable markets 97 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Agency— Overview Geographic Focus within Funding source Africa results/ program focus the clean cooking targets sector West WACCA, under Member of • Promotes the ECOWAS Status: Regional African Clean leadership of the Economic implementation framework Cooking Alliance the ECOWAS Community of regional development; two (WACCA) Centre for Clean of West policies on clean national pilots and Renewable African States cooking launched (2012—ongoing) Energy and (ECOWAS) • Capacity Target: Aims to Energy Efficiency, building for reach 13 million aims to clean cooking households (20% provide access initiatives of households) to efficient, in the ECOWAS • Support on sustainable, region with clean harmonizing and affordable and efficient standards cooking energy; cooking energy by and labeling implemented 2020 practices with ETC- ENERGIA, GACC, • Promotion of Africa Energy networking Agency, GERES, and knowledge GIZ, and ICEED sharing Global LPG GLPGP is a Ghana, • Joint planning KfW, LPG industry Target: Transition Partnership public–private Cameroon, with national 50 million people (GLPGP) partnership that Kenya; stakeholder to in Africa to LPG by aims to enable expansion plan transition 2016–17; transition (2014, ongoing) governments, likely to strategies for LPG 1 billion people the private Nigeria, adoption globally to LPG sector, and Tanzania, • Policy advocacy from cooking with consumers to Uganda solid fuels by 2030 • Investing in scale up access infrastructure, to and use of SMEs, and clean-burning consumer LPG for cooking finance in Africa, Asia, and Latin America Africa Biogas The ABPP is a Burkina Faso, • Results-based Directorate General Status: >40,000 Partnership partnership Ethiopia, program for International biogas plants Programme between Kenya, working with Cooperation of the installed by 2014 (ABPP) Hivos and SNV Tanzania, local country Dutch Ministry of Target: 100,000 supporting Uganda partners Foreign Affairs and target by program (2009–14; national • Works to build SNV (Netherlands completion in 2014–17) programs on an enabling development 2017 domestic biogas environment organization) in five African allowing the countries, biogas sector to with the aim flourish of sustained • Provides training construction of for private domestic biogas companies plants as a local, and local sustainable organizations energy source and, ultimately, • Engages with development of local financial a commercially institutions viable and • Raises awareness market-oriented among potential biogas sector end users 98 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Agency— Overview Geographic Focus within Funding source Africa results/ program focus the clean cooking targets sector Biomass BEIA was Benin, DRC, • Creating AFREA supported Results: Nine Energy Initiative an effort Ethiopia, The enabling market by US$28.75 pilot projects for Africa (BEIA) implemented Gambia, Kenya, conditions for million from the completed across by the World Rwanda, high-quality Netherlands in Africa; five of the (2010–15) Bank’s Africa South Africa, and high- 2008 under the nine have secured Energy Team to Tanzania, performance Energy Sector additional funding test innovative Uganda modern cooking Management from different and promising stoves Assistance donors for scale- biomass energy • Modernizing the Program’s Clean up activities initiatives charcoal industry Energy Investment that have the Framework Multi- • Demonstrating potential to be donor Trust Fund the feasibility of incorporated social biofuels into the future WB lending • Increasing power portfolio capacity with bioelectricity • Building capacity and strengthening leadership in biomass energy Global Village DEEP was a five- Kenya, • SME capacity EU and the Dutch Results: >400 Energy Partnership year initiative Tanzania, building Ministry of Foreign cookstove/ (GVEP)— promoting the Uganda • Policy Affairs liner enterprises Developing development engagement created and Energy Enterprises of a sustainable supported; • Financing for Program (DEEP) and widespread >200,000 ICS entrepreneurs industry of distributed (2008–12) micro and small • Market linkages annually by 2012 cooking energy enterprises in East Africa United UNEP operates in Ghana, Mali, • AREED provided Funding from UNEP Results: 24 Nations Africa to develop Senegal, early- and later- and the Swedish sustainable rural Environment new sustainable Tanzania, stage financing International energy enterprises Programme energy Zambia to peri-urban Development in place by 2009; (UNEP)—Africa enterprises LPG and rural ICS Cooperation >50,000 ICS and Rural Energy that use clean, suppliers Agency in most LPG households Enterprise efficient, and • Equity and debt recent phase of reached; Development renewable investments AREED US$7–10 million (AREED) energy were made of financing technologies; in higher-risk mobilized (2000–8, 2009–12) E+Co served enterprises; as the financing often implementing was provided agency during jointly with the first phase of local and the program microfinance institutions • Microfinance lending to end users 99 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Agency— Overview Geographic Focus within Funding source Africa results/ program focus the clean cooking targets sector Gesellschaft für ProBEC was Botswana, • Promoted The governments Status: 250,000 Internationale a decade- DRC, Lesotho, various stove of Germany and households using Zusammenarbeit] long initiative Malawi, and fuel The Netherlands ICS by program (GIZ)—Programme supported by Mozambique, technologies: completion in for Basic GIZ that ended Tanzania, wood, charcoal, 2010 Energy and as a supported South Africa, biofuels, biogas Conservation program in 2010; Swaziland, and solar cookers (ProBEC) some activities Zambia • Trained local have since producers (1998–2010) continued as a • Offered policy Southern African advisory to Development improve Community stakeholder (SADC) initiative coordination • Monitored sector progress via consumer and producer surveys Sources: Press searches; program documentation; interviews; Dalberg analysis. 100 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Despite their increasing number, few national programs in SSA have achieved large-scale stove distribution or created sustainable markets. Among the larger, more successful programs have been those in Ethiopia, Kenya, Senegal, Tanzania, and Uganda. Tanzania’s program, led by NGO TaTeDo with initial support from GIZ, distributed an estimated 2 million stoves from 2000 to 2010. As of 2006, national programs in Kenya, Senegal, and Uganda reached approximately 3 million, 200,000, and 80,000 households, respectively. Ethiopia’s national program, which is ongoing, has reportedly reached several million households and has been the biggest success at scale to date in increasing basic and intermediate ICS penetration. While the various SSA national programs vary in terms of national government role, business model, and level of ambition, there are similarities. Most national cookstove programs pursue commercial or hybrid models; very few, like the Rwanda initiative to distribute 600,000 rocket stoves to poor rural end users, are entirely covered by subsidies. The focus of early national programs in Africa has almost exclusively been the environment (deforestation and climate change) and rural livelihoods, but improved health outcomes are increasingly becoming an important focus. Other important trends for the more successful national programs include intensive focus on R&D, increasing attention paid to standards, and diversification from a focus on stove subsidization toward more holistic approaches involving the entire supply chain. Common problems include overreliance on subsidies and inadequate consumer training to complement stove distribution. Looking across the range of models, approaches, and tools used by the various national and regional cookstove programs, there are a variety of lessons to be drawn. From the experience of both governments and donor agencies, it is apparent that in the early stages of stove promotion programs, subsidization—in some form or another—played an important role. The question of whether subsidies should be provided has been hotly debated in the sector. The experience of various national-level programs shows clearly that, despite the dichotomous “yes or no subsidies” debate by some stakeholders, the impact of a subsidy depends enormously on elements of its design—that is, its mode of provision (direct/indirect), its value (high/low), and the time for which it is provided (full time/phased out). Ultimately, this experience has shown that some degree of subsidization may be required in the early stage of any effort to increase improved stove adoption. However, there are three key caveats: subsidies should be introduced with a very clear phase-out plan and should not be permanent; they should be of the lowest possible value to provide the needed support while not diminishing the value of the product; and they should clearly target the appropriate consumer and product segments— namely, the very poor (and often rural) communities and the high-performance, high-cost stoves where the benefits of use are significant but upfront costs are prohibitive. A second set of lessons can be learned about the importance of early and sustained consumer engagement across the value chain. African cookstove programs have been most successful where product design has been carefully developed to accommodate user preferences, cooking practices, and behaviors. Conversely, adoption has been difficult where this was not the case, requiring multiple iterations of design and pilot. Particularly important in the design phase is consultation with women: where programs actively engaged women (as the ultimate users and often buyers of the stoves) in the design of the product, adoption has been more successful. Overall, where communities were engaged in the whole process of program design and inception, training, and development of artisans and enterprises, marketing and sales—as well as the crucial stage of feedback and monitoring—programs have had a deeper and more sustained impact. Finally, crucial to note from the programs outlined in this section is the importance of engaging in the sector with a medium- to long-term time horizon. Most successful national programs take 5–10 years to achieve meaningful scale, with the greatest impact often seen after program completion. Although scaling up improved cooking solutions in Africa has historically relied heavily on both direct and indirect subsidies, the more market-based approaches have worked best. Modern cooking fuels have had the widest reach in Africa in places where governments have injected significant fuel subsidies into the sector. This includes Angola, Cameroon, Côte d’Ivoire, Ghana, and Senegal in the case of LPG; Nigeria in the case of kerosene; and South Africa, Zambia, and Zimbabwe in the case of electric cooking. While tens of millions of households have gained access to modern cooking energy in the past few decades as a result, many of these countries have eliminated or lowered fuel subsidies in recent years because of fiscal pressures, with the result being slower growth or retrenchment in the number of low- or moderate-income households with access to clean fuels. The distribution of renewable stoves has likewise been based on direct subsidies. Most solar cookers, for example, have been distributed at no cost via NGO efforts, and African biogas digester installations involve substantial subsidies (20–50%) for upfront system costs. 101 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report In contrast, the biggest African successes in scaling up access to improved biomass cooking solutions have involved public-sector or donor-driven cookstove programs with strong market-based logic. The Kenya ceramic jiko technology, for instance, after two decades of donor and government promotion, cross-border replication, and transition to market-based distribution, now reaches more than 25 million Africans in at least 14 countries as the baseline charcoal-cooking solution in many urban centers. Other successful examples of improved cookstove distribution at scale include Mirt injera stoves in Ethiopia (more than 2 million units distributed, greater than 60% urban household penetration); Rocket Lorena stoves in Uganda (more than 500,000 households); and brick and mud rocket stoves in Kenya (more than 1 million households). Self-reported data from the GIZ/ProBEC and EnDev programs linked to a number of these stove technologies show that the programs have extended access to basic and intermediate ICS to more than 15 million Africans in less than a decade. Although indirect subsidies and market facilitation were required at early stages of all of these programs, the most successful efforts have minimized direct subsidies and relied on enterprise-based and market-based mechanisms for growth. Challenges to the Enabling Environment Despite promising trends, many policy and institutional challenges remain in the stove and fuel markets. The most notable gaps in the enabling environment have to do with tax and tariff policies, the infrastructure for cookstove quality testing, regulations on biomass and modern fuels, and access to finance. Stove taxes and Tariffs Taxes and import tariffs in many countries are set at levels that significantly reduce consumers’ access to high- quality clean cooking appliances. Alternative domestic products are unavailable in most of SSA because of technical and infrastructure constraints. Paradoxically, taxes and tariffs may also impede the development of domestic assembly markets by taxing the import of stove components. Infrastructure for Cookstove Quality Assurance Despite the development of new ISO IWA stove standards and the launch of four regional testing centers across Africa with the support of the GACC, cookstove quality standards and testing are still a significant gap. The provisional ISO standards, while an important step forward, have limited awareness and buy-in among local African stakeholders; local standards are not aligned to the provisional ISO guidelines; many local African stove models remain untested; and the build quality of artisanal products distributed via pure private-sector channels (e.g., Kenya ceramic jiko-style stoves) is often low. Regional testing centers have limited funds and human resource capacity, testing costs are prohibitively high for many potential users (e.g., artisanal and semi- industrial manufacturers), and reliable in-field testing programs involving cookstove usage monitors and field emission meters still require the involvement of costly international experts. Even in the future, when stove test results will be obtained and regularly updated for a comprehensive set of clean and improved SSA cooking solutions, the major challenge will remain of ensuring that sector stakeholders integrate them into stove design and distribution decisions. There is therefore a need for a sector quality assurance program, such as the activities of the World Bank ACCES initiative on this issue, that can ensure that such results provide incentive for improvement, reveal technical support areas, and guide quality control measures that need to be put in place. Regulation of Biomass and Modern Fuels African governments have focused their domestic cooking energy policy efforts on promoting modern fuels, rather than the sustainable harvesting and use of woodfuel biomass. Policies, such as charcoal bans (in place throughout the continent), insufficient investment in forestry management, and poor incentives throughout biomass fuel supply chains, impede more rational biomass fuel use that can complement demand-side efforts to reduce biomass consumption and supply-side policies that promote modern and alternative renewable fuels. With regard to modern fuels, stronger regulatory frameworks and investment are needed across the SSA region to ensure consumer safety and channel capital to large-scale infrastructure development (i.e., storage 102 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report and transport infrastructure). Safety is a particularly important concern for LPG markets, where weakly defined certification and licensing policies, the absence of training for fuel distributors, and limited enforcement of existing regulations are major obstacles to consumer uptake. Additionally, tax and subsidy regimes for modern fuels are often poorly implemented, with unsustainable subsidies that have regressive outcomes and contribute to sporadic fuel shortages. Specific protocols are required for transporting, storing, and using such liquid fuels as LPG and kerosene safely. Appropriate training must extend through the value chain to small-scale distributors to prevent accidents. SSA countries lack the certification and licensing to ensure such handling, in part because the physical infrastructure for safely transporting liquid fuels is not in place. Pursuit of stronger standards and requirements for fuel distributors, in conjunction with joint investments in infrastructure, would increase the integrity of the value chain and effective distribution of liquid fuels. Consumer education is especially important for LPG and kerosene, because they are responsible for proper storage and operation after sale.201 Malfunctioning LPG canisters can cause explosions, and improper fuel storage poses risks to the entire household; 60% of child- poisoning incidents in Kenya and South Africa are a result of accidental ingestion of kerosene.202 As such fuels as LPG become increasingly affordable, SSA governments will need to work with companies to disseminate safe-use guidelines and minimize risks to public health. Lack of Access to Finance Lack of access to finance is another major, cross-cutting obstacle to faster market-based growth. At the micro level, the challenge cuts across the value chain. Manufacturers and distributors, like any SME in Africa, are often unable to access credit to fund product innovation, distribution network development, and consumer marketing. For cash-strapped consumers who often lack disposable income for upfront purchases of improved cookstoves, few microfinance institutions (MFIs) or retail banks focus on clean cooking—and, in any case, traditional financing solutions often do not work in this sector because of the high transaction costs involved relative to cookstove costs. Despite these challenges, there is great promise in a number of existing and innovative financing mechanisms across the cookstove and fuel supply chain. Carbon financing has played an important role in accelerating improved cookstove uptake in Africa in the past few years—particularly for more expensive (US$30–100) industrial and semi-industrial ICS or clean ACS, most of which have been sold via manufacturers or distributors that have access to CDMs and voluntary carbon market schemes. The continued and growing importance of the carbon market is well illustrated by the fact that, despite depressed carbon prices, half of the 8.2 million stoves distributed and sold in 2012 (as tracked by the GACC) received some support from carbon finance projects. This support is up from 15% in 2010–11.203 Carbon credits, via 21 registered CDM projects204 and 33 registered and listed Gold Standard VER (verified emission reduction) projects205 covering 19 SSA countries206 have allowed manufacturers to reduce end-user prices by 20–50% and/or use the proceeds from carbon financing to invest in distribution and generate higher returns for their investors. While the prospects for the carbon market are uncertain in a post-Kyoto scenario, stove CDM project registrations are continuing at a fast pace (nine SSA projects in 2013), and the voluntary market for stove projects is booming, with Africa overall accounting for a disproportionate share of global cookstove program offsets (Figure 58). Carbon credits will not, however, pay for the incremental health benefits of clean cooking solutions. The carbon reduction potential of most ACS, such as fan and ND gasifiers, is often proportional to fuel efficiency— which, in many cases, is comparable between intermediate ICS and ACS. For instance, a high-performance wood rocket stove, despite its relatively limited health benefits, may be able to generate 50–70% carbon savings—a result comparable with some of the best ACS. Against this background of comparable carbon emissions performance, the 1.5–4-times price differential between industrial ACS (US$75–120) and high-quality industrial rocket ICS (US$20–80) suggests that carbon project developers interested solely in carbon impact will prefer technologies that have fewer positive health impacts. To avoid such outcomes, new financial incentives—social impact bond revenue streams, for example, or results- based financing (RBF) facilities linked to health—are needed to drive socially desirable investment toward the sector. The Department for International Development is already experimenting with an RBF approach through a dedicated RBF fund, with an RBF pilot in progress to facilitate the extension of cookstoves to 200,000 103 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Figure 58: State of ICS carbon finance market (2013) Number of cookstove CDM projects Annual cookstove program and PoAs submitted offsets by region VCS VCUs PoAs GS VERs Projects CDM CERs (Projects & PoAs) Average annual offsets issued (MMtCO2e/yr) 70 9.0 8.0 60 Number of projects & PoAs 7.0 50 6.0 40 5.0 30 4.0 3.0 20 2.0 10 1.0 0 0.0 2008 2009 2010 2011 2012 Africa Asia & Pacific Latin America Note: Annual cookstove o set data include both registered and validation-stage projects. Gold Standard (GS) projects include registered and listed projects. Veri ed carbon units (VCUs) are credits issued under the veri ed carbon standard (VCS). PoA = program of activities. Source: Lee et al. (2013), drawing on data from UNEP Risoe Centre, and the gold and veri ed carbon standards. rural households in Ethiopia.207 The feasibility of applying RBF mechanisms for clean and improved cooking solutions in Africa is also currently being explored in World Bank-sponsored research in Uganda,208 Indonesia, and elsewhere. While there is no commercial market for clean cooking impacts, there are a number of important efforts under way to explore such approaches, with immediate potential application to Africa. The C-Quest Capital team, for instance, drawing on its carbon finance market expertise, is exploring the potential to create a CDM-like market for cookstove health impacts, and is working on piloting a potential new RBF methodology.209 Similarly, the newly launched BIX fund, while most immediately focused on carbon finance revenues, is working on a methodology to package cookstove health impacts for social impact investors.210 Although downstream financing for micro-entrepreneurs and consumers is also a major need, affordability challenges are more likely to be addressed through innovative pay-as-you-go models. Further downstream, micro-entrepreneur financing programs for last-mile cookstove retailers are beginning to generate interest from large African MFIs, such as FINCA. They have already been piloted by financial institutions, such as KUSSCO and FAULU in Kenya, though as yet few dedicated cookstove-financing programs are in place. For end-consumer finance, extensive cooking-sector interviews and examples from other industries (such as solar lighting) suggest that the biggest potential resides in (1) replicating pay-as-you-go schemes of the type piloted by Toyola Energy in Ghana; (2) extending new mobile-metering/payment models, such as those from M-Kopa, IndiGo, and Angaza to the cookstove sector; and (3) integrating the fuel/stove business model (i.e., building upfront stove costs into the fuel price) that Inyenyeri has pioneered in Rwanda for biomass pellet stoves and that CleanStar and Green Energy & Biofuel have applied to ethanol stoves in Africa. Figure 59 summarizes the more recent innovations in financing models. 104 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Figure 59: Clean and improved cookstove funding Option Details Example Installment/PAYG • Consumers can pay for a stove in plans installments • Pay-as-you-go systems lower upfront costs for consumers, but transaction costs of collection are high and difficult to scale Carbon finance • US$20–80 carbon credit is claimed (CDM) by the manufacturer as income over the stove’s life and partly passed on to consumer as a subsidy • US$42 million in CDM funds channeled to stoves projects last year, but viability at scale unclear given state of carbon credit markets Microfinance • Small loans for stove purchase disbursed through MFIs and savings and credit cooperatives, and typically bundled with distribution arrangements • No demonstrated capacity for scale today due to logistical challenges and low MFI appetite for financing $25 that is slightly 70%; up to 80% reductions fuel better than basic CO reduction combined • Very high charcoal ICS to very compared with modest cost (though dramatic efficiency to traditional PM decreases the payback and emissions charcoal stoves (relative to period can be improvements for already low rapid in high- newest top-end charcoal PM cost charcoal design levels) mean markets) that stoves can approach gasifier emission levels at very top of range 128 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report ADVANCED BIOMASS COOKSTOVES (ICS) Stove type Description Examples and Performance Advantages Disadvantages illustrative prices indicators Natural-draft • These stoves • Awamu Troika • Tier 2–3 • Highly efficient • Relatively high gasifier ACS use gasification TLUD: $18 (at for indoor stoves with price and principles due manufacturing emissions, Tier 3 low levels of still few local to the shape of site) for efficiency emissions production their combustion • Sampada • Often produce models chamber—fuel Gasifier stove: bio-char/ • Often requires (wood/charcoal/ $20 charcoal­—can significant agricultural waste) be used for behavior • TLUD stove is pyrolyzed in the fertilizer or sold change, (Servals): $32 gas chamber, the including top • Lucia • TChar variants flue gases then are loading of WorldStove: can be allowed to mix with a fuel and fuel $30–50 integrated fresh draft of air and preparation with charcoal burned • Peko Pe/ (e.g., breaking cooking (i.e., • Stove is usually made Wandelbo wood into little char produced of metal: stainless TLUD: $10+ (not pieces) if pellets during steel/aluminum; widely available not used gasification artisanal/semi- commercially, can be used as • High variability industrial versions but $2–5 charcoal) of performance will often have wood production • Often use across models parts (e.g., Awamu cost) a variety of Troika) • Vesto: $30–50 fuel: wood, • Typical natural- • Greentech agricultural draft gasifiers are (The Gambia) waste top-lit up-draft “rockifier”: $15 (TLUD) designs, but some side-loading “rockifier” designs (e.g., GreenTech stove in The Gambia) also exist Fan (“forced- • Stoves that rely • Philips/ACE • Tier 3 for indoor • Made of • Stoves updraft”) on gasification smokeless emissions, light-weight optimized for gasifier ACS principles with the stove (Philips nearly and advanced pellet fuel use; secondary draft HD4012): approaching materials and perform less of air aided by a $75–100 Tier 4 at top are ultra- well if wide battery-powered fan • Philips/ACE end of range; portable variety of fuels component AE-1 stove Tier 3–4 for • Fans enable needed • Usually made of efficiency effective mixing • Instructions • Oorja stove stainless steel/ of air, and must be closely aluminium and could • Up to 95% gasification followed include a rocket- reduction in helps reduce to realize type combustion emissions, can incomplete efficiency gains chamber reach 70–80% combustion • Addition of fans fuel savings, • Stove can increase price particularly with charge LEDs by $5–10 and pellet fuels and phones may reduce durability Electricity- • Fan gasifiers that • Biolite TEG • Tier 3 for • All of the pluses • Same generating convert heat to Home Stove: emissions, of battery- disadvantages ACS electricity and $45–65 Tier 3–4 for powered fan- as broader power stove’s fan efficiency gasifier stoves, fan-gasifier and, potentially, plus additional stove family, other appliances like advantages of with particular mobile phones reduced cost of challenge on 129 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Stove type Description Examples and Performance Advantages Disadvantages illustrative prices indicators Electricity- • Currently only • New ACE 1/ • ownership stove cost due generating one model on the Philips uses (i.e., no need to the need ACS African market, 5W solar for battery to include cont’d BioLite HomeStove, a panel/battery replacement) both fan and side-loading gasifier technology and improved electricity- that powers fan to deliver value generating with thermoelectric solar lighting proposition components generation (TEG); and mobile due to mobile • Long-term BioLite’s new charging phone- durability Kettle Charge functionality charging requires product utilizes • Score-Stove capabilities ongoing TEG technology to thermoacoustic testing, as generate 10W of stove prototypes electricity from any (prototype only, are relatively stove/hot surface. tested in Africa) new and have • Other new stove • Several only recently technologies with manufacturers been deployed electric device exploring with some charging capabilities launch of TEG scale in African are powered by models in 2015 conditions solar panel/battery and off-brand • Some stove combos (e.g., ACE 1) models are models in marketed in this category China, but incorporate feasibility of batteries into new large- the design, scale entrants which require with this periodic technology is replacement unclear due to (e.g., every 3–4 BioLite patent years) restrictions MODERN FUEL AND RENEWABLE FUEL STOVES LPG • Single and • Single-burner • Tier 4 for • High calorific • Expensive multiburner stoves LPG stoves: efficiency, Tier value, delivers cooking burning liquefied $10–50 4 for indoor double the heat solution and petroleum gas (LPG) • Multiburner emissions for the same very expensive from pressurized stove: $50–90 • Clean cooking amount of fuel cylinders fuel at point of kerosene • Danger of • Stainless steel/metal use; very low • Fast cooking explosion stove emissions and time • Stove usage • Some LPG stove high efficiency is heavily manufacturing based dependent in Africa (e.g., South on fuel supply, Africa, Togo), but vast which is limited majority imported in most of from Asia Africa Kerosene • 2 types: pressure • Basic kerosene • Tier 3–4 for • Fast cooking • Wick stoves stoves and wick type stoves: $5–20 efficiency, Tier • Inexpensive burn with a stoves (wick-type • More advanced 3–4 for indoor stoves lot of soot as can be single wick or kerosene stoves emissions opposed to heater-type circular (e.g., Servals, • Kerosene pressure stoves wick) Arivi): $10–40 stoves produce • Expensive fuel little or no CO emissions 130 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Stove type Description Examples and Performance Advantages Disadvantages illustrative prices indicators Kerosene • In pressure stoves • Widespread • Danger of cont’d the fuel is preheated fuel availability kerosene burns before undergoing in most parts if stove falls combusion; pressure of Africa, given over is provided by a the lighting • High non-PM pressure pump uses of paraffin/ toxic particle • In wick stoves, the kerosene emissions wick drives fuel to burner; usually made of metal, such as brass Electric • Electric cookstoves • Wide range of • Tier 4 for • Commercial • Most expensive convert electrical costs: $15–50 efficiency, Tier stoves are cooking energy into heat for single 4 for indoor highly durable, solution in • Single-burner and burner; $40– emissions extremely Africa, aside double-burner 150 for double efficient, easy to from 2–3 models in use in burner; >$150 maintain subsidized urban Africa for electric markets induction • Low grid • Induction cookers cookers penetration in generate heat via an oscillating magnetic SSA field and are highly • Unreliable efficient power services make regular cooking with electricity difficult Alcohol • Fuel, such as plant oil, • CleanCook: • Tier 3–4 for • By-products of • Needs a ethanol, methanol $50–80 efficiency, tier oil processing separate fuel- burned in liquid, • Lower-cost, 3–4 for indoor or ethanol supply chain solid, gel forms lower-quality emissions making can be • Fuel usage will • Fuel needs to be ethanol gel used as fertilizer depend on produced from stoves available: or fodder local sources processing of $25–50 • Stoves are available for sources, such as oil durable— processing seeds, cassava lasting for up to • Stoves are • The fuel is collected 10 years expensive, in small tanks, and • Stoves are mostly catering pressurized to be convenient and to urban used on burner-style safe • May not burn stoves as hot as LPG Biogas • Stoves have to • Traditional • Tier 4 for • The fuel used • Need sufficient accompanied by a digesters: efficiency, Tier is renewable feedstock biogas plant, which $1,000–1,500 4 for indoor biomass/waste (dung) produces methane w/o subsidy, emissions • The residue in • High upfront from biomass burner is • Cleaner than the tanks can costs • Pressured gas from $10–30 LPG be used as • Ongoing tanks is burned on • Small-scale fertilizer maintenance burner-style stoves digester requirements • ABPP distribution (SimGas): program $500–800 131 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Stove type Description Examples and Performance Advantages Disadvantages illustrative prices indicators Solar cookers • Direct solar thermal • CookIt: $10–20 • Tier 4 for • Absolutely the • Slow cooking energy can be used • Parabolic solar emissions; 100% cleanest source • Quality stoves to power solar ovens: >$100 fuel savings of cooking are fairly cookstoves theoretically, energy expensive • Box cookers: • A variety of designs though stove • No ongoing $50–150 • Dependent on available from global use limited to costs once the light availability experience: foldable/ sunny days solar oven/ and therefore low-cost materials, cooker is a secondary box cookers, purchased solution parabolic reflectors Note: All monetary values are in U.S. dollars. Sources: Press searches; interviews; desk review; GACC Stoves Catalog (http://catalog.cleancookstoves.org); Dalberg analysis. 132 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Appendix 2: Provisional Standards for Improved and Clean Cookstoves Table 2.1: Provisional ISO/IWA tier classifications for clean and improved cooking technologies Proposed Safety Fuel use Emissions (CO + PM) (stove rating will be Indoor emissions Illustrative ISO tier rating (thermal based on the lowest score from the four stove type (Iowa efficiency) criteria) State Univ. (%) CO CO PM PM CO PM Rating (g/MJ) (g/min/L) (mg/MJ) (µg/min/L) (g/min) (µg/min) System) Tier 0 <45 <15 >16 >0.2 >979 >8 >0.97 >40 3-stone fire Improved efficient Tier 1 ≥45 ≥15 <16 <0.2 <979 <8 <0.97 <40 charcoal stove (KCJ type) Rocket stove; Tier 2 ≥75 ≥25 <11 <0.13 <386 <4 <0.62 <17 natural- draft gasifier Forced- draft “fan”- Tier 3 ≥88 ≥35 <9 <0.1 <168 <2 <0.49 <8 gasifier stove Tier 4 ≥95 ≥45 <8 <0.09 <41 <1 <0.42 <2 LPG stove Figure 2.1: Cookstove ISO standards development process Standards Development Process Working group First working National of experts start draft shared Discussions International discussion with technical adoption and convened by standards to prepare a committee and implementation GACC development working draft with ISO CS* of standards Develop Follow established Follow established protocol procedures procedures Draft shared Draw tiers for Status: International Final draft with all ISO Testing and sent to all ISO members for certification protocols Workshop Agreement members comments in February 2012 and Labeling and Standardize new ISO technical enforcement reporting committee established guidelines in June 2013 Status: ongoing First working Technical committee discussions draft shared with meeting scheduled for technical committee November 2013 and wih ISO CS Source: Global Alliance for Clean Cookstoves (2012), available at http://www.cleancookstoves.org/resources_files/results-report-2012.pdf 133 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Appendix 3: METHODOLOGY FOR SIZING SOLID-FUEL COOKING OPPORTUNITY COST Our SSA impact model incorporates commonly attributed economic, health, and environmental impacts of solid-fuel cooking and represents the total economic value—or opportunity cost—foregone annually because of reliance on solid fuels. This is considered in relation to a best-case scenario of full adoption of higher- performing ICS by African households, intermediate Tier 2–3 rocket stoves at the bottom of the range, and Tier 3–4 gasifier biomass stoves at the top of the range. Naturally, the precise numbers will vary based on the assumptions used and on the counterfactual baseline. For instance, in an alternate scenario where households that currently pay for solid fuels are shifted to LPG and biomass fuel collectors are shifted to high-performing ICS, the mid-range opportunity cost of solid-fuel cooking would be $27 billion, with higher health and environmental benefits and lower economic savings due to the relatively high costs of LPG fuel use. Independently of the precise scenario used, however, it is clear that the magnitude of the opportunity cost is in the high tens to the hundreds of billions of dollars. For economic impact, key variables are avoidable economic values of solid-fuel spending, firewood collection time, and cooking time. For health impacts, the model includes the economic costs of the most recent Lancet HAP-related morbidity and mortality estimates, with the addition of burns linked to traditional solid-fuel stoves and minor eye conditions linked to indoor smoke exposure. For environment and climate change impacts, the model estimates the costs of deforestation (valued via potential afforestation costs) and the carbon credit value of avoidable GHG emissions. The opportunity costs of time and related values throughout the model (e.g., cost of death due to HAP) are based on average gross national income for the SSA region and agricultural value added using human-capital methodology. Cooking-fuel mix and fuel-use data draw on an up-to-date database of national fuel consumption surveys for all 47 SSA countries. The core methodological framework is derived from Hutton et al. (2007) and Jeuland and Pattanayak (2012). Underlying assumptions are derived from the extensive existing literature on solid-fuel impacts, with strong weighting toward SSA examples. Table 3.1: Economic losses and opportunity costs in SSA from dependence on solid fuel in 2010 (US$ billions) Cost category Low Mid-range High Health $0.6 $5.0 $9.4 Mortality for HAP $0.3 $3.5 $6.8 Morbidity for HAP $0.2 $0.7 $1.1 Other health conditions (burns and eye disease) $0.1 $0.8 $1.5 Environment & climate change $0.6 $6.3 $11.9 GHG emissions—fuel consumption $0.2 $2.1 $3.9 GHG emissions—charcoal production $0.2 $0.7 $1.2 Deforestation $0.2 $3.5 $6.7 Economic effects $4.2 $20.6 $36.9 Spending on solid fuels $0.4 $3.8 $7.3 Time wastage (fuel collection) $0.6 $6.5 $12.4 Time wastage (cooking time) $3.3 $10.2 $17.2 Total $5.4 $31.8 $58.2 Sources: Opportunity cost sizing model; Dalberg analysis. 134 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Appendix 4: Methodology for Calculating SSA Fuel Mix and Fuel Mix Evolution The regional fuel mix was calculated by aggregating household survey data for 45 SSA countries based on data maintained by the WHO Global Health Data Repository and/or from underlying country surveys from the Demographic and Health Surveys (DHS) Program, the Multiple Indicator Cluster Survey (MICS), the Living Standards Measurement Study (LSMS), or national census sources for the most recent year available. As a proxy for the year 2000, the analysis used household survey data from 1998 to 2002, depending on the country; for the year 2010, 2007–12 data were used. Only actual survey data were used—the aggregated results were triangulated with WHO parametric estimates for 2010, but WHO parametric data were not used. Survey data were cleaned to ensure that rural and urban mix data tallied to country totals, and absolute counts of fuel-user populations were computed by multiplying fuel mix with UN population estimates. The regional fuel mix was projected to 2015 and 2020 by computing the historical annual changes in fuel share for each fuel (2000–10) for both rural and urban areas, assuming that the historical change will continue going forward in a linear fashion through 2020, and remixing the forecasted urban and rural fuel shares by UN forecasts for rural and urban population for each country. In effect, this analysis derives an “inertial case” fuel mix for each cooking fuel, adjusted for population growth and urbanization rates. At a country level, this approach may be inaccurate (it does not take into account differential GDP growth, for example), but at the regional level the data are likely robust and fit well with IEA/OECD 2010 projections for the overall African solid-fuel population (about 850 million in 2020). Table 4.1: SSA population by primary cooking fuel (millions) Fuel 2000 2010 2015 F 2020 F Electricity 30 46 56 68 LPG 23 37 47 58 Natural gas 1 2 2 3 Kerosene 52 56 57 58 Coal 7 10 11 13 Charcoal 61 109 143 188 Wood 470 572 615 663 Dung/crop waste 12 15 16 20 Other 10 7 5 4 Total 667 854 953 1,073 Modern fuel 107 142 162 186 Solid fuel 550 705 786 883 Other 10 7 5 4 Total 667 854 953 1,073 Note: F = forecast. Sources: SSA country fuel mix database; Dalberg analysis. 135 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Appendix 5: SSA fuel mix Table 5.1: Country fuel mix data Ag. waste/ Electricity LPG/LNG/ Solid-fuel Kerosene Charcoal biogas Wood Other Dung share straw Coal Year Country Angola 2009 33% 1% 4% 0% 19% 42% 0% 0% 1% 62% Benin 2012 6% 0% 0% 1% 26% 65% 1% 0% 1% 94% Botswana 2006 46% 7% 3% 0% 0% 43% 0% 0% 0% 44% Burkina Faso 2010 5% 0% 0% 0% 4% 88% 0% 0% 3% 95% Burundi 2010 0% 0% 0% 0% 8% 85% 6% 0% 1% 100% Cameroon 2011 18% 0% 4% 0% 2% 71% 1% 0% 3% 78% Cape Verde 2006 64% 0% 0% 0% 0% 34% 0% 0% 2% 36% Central African Republic 2010 0% 0% 0% 0% 3% 96% 0% 0% 1% 100% Chad 2010 2% 0% 0% 0% 3% 93% 1% 1% 1% 98% Comoros 2011 4% 1% 18% 0% 2% 73% 0% 0% 2% 77% Congo (Brazzaville) 2012 15% 1% 11% 0% 33% 38% 0% 0% 1% 72% Côte d’Ivoire 2012 15% 0% 0% 0% 18% 60% 0% 0% 7% 85% Democratic Republic of the Congo 2007 0% 4% 0% 0% 25% 71% 0% 0% 0% 96% Djibouti 2006 5% 1% 81% 0% 9% 4% 0% 0% 1% 14% Equatorial Guinea 2012 18% 1% 35% 0% 1% 42% 0% 0% 3% 46% Eritrea 2009 3% 0% 16% 0% 10% 60% 0% 10% 1% 81% Ethiopia 2011 0% 1% 2% 0% 8% 78% 2% 7% 2% 97% Gabon 2012 79% 0% 1% 0% 1% 13% 0% 0% 5% 20% Gambia, The 2010 1% 0% 0% 0% 12% 85% 0% 0% 2% 99% Ghana 2011 17% 0% 0% 0% 29% 50% 1% 0% 2% 82% Guinea 2012 0% 0% 0% 0% 29% 69% 0% 0% 2% 100% Guinea-Bissau 2010 1% 0% 0% 0% 31% 68% 1% 0% 0% 99% Kenya 2009 5% 0% 5% 1% 16% 72% 2% 0% 0% 90% Lesotho 2009 21% 6% 7% 0% 0% 49% 7% 8% 1% 66% Liberia 2007 0% 0% 0% 0% 39% 59% 0% 0% 1% 100% Madagascar 2011 1% 0% 0% 1% 21% 76% 0% 0% 1% 99% Malawi 2010 0% 2% 0% 0% 10% 86% 2% 0% 0% 98% Mali 2006 0% 0% 0% 0% 16% 80% 0% 2% 1% 100% Mauritania 2011 38% 1% 0% 0% 20% 40% 0% 0% 1% 61% Mozambique 2011 3% 1% 0% 1% 15% 80% 0% 0% 1% 97% Namibia 2006 7% 34% 0% 0% 1% 55% 0% 0% 3% 58% Niger 2012 1% 0% 0% 0% 2% 86% 7% 2% 2% 99% Nigeria 2013 2% 0% 26% 0% 3% 64% 2% 0% 3% 72% Rwanda 2010 0% 0% 0% 0% 10% 89% 0% 0% 1% 100% Senegal 2011 32% 1% 0% 0% 12% 53% 0% 1% 1% 67% Sierra Leone 2010 0% 0% 0% 0% 0% 14% 0% 83% 2% 100% Somalia 2005 0% 0% 0% 0% 33% 66% 0% 0% 0% 100% South Africa 2007 2% 66% 15% 1% 0% 15% 0% 0% 0% 17% South Sudan 2010 8% 0% 0% 18% 2% 70% 1% 1% 0% 91% Sudan 2006 0% 0% 0% 0% 14% 81% 3% 0% 1% 100% Swaziland 2010 11% 17% 3% 0% 0% 69% 0% 0% 0% 70% Tanzania 2010 0% 1% 3% 0% 21% 74% 0% 0% 1% 96% Togo 2010 2% 0% 0% 0% 39% 59% 0% 0% 0% 98% Uganda 2011 1% 0% 1% 0% 23% 73% 0% 0% 2% 98% Zambia 2007 0% 15% 0% 0% 25% 60% 0% 0% 0% 85% Zimbabwe 2011 0% 28% 2% 0% 0% 69% 0% 0% 1% 70% Sources: WHO, DHS, MICS, National Census data, Dalberg analysis (rounded to nearest percentage point). Data are as of July 2014. 136 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Table 5.2: Detailed country fuel mix data—latest available, as of July 2014 Ag. waste/ Electricity LPG/LNG/ Solid fuel Kerosene Charcoal Modern Source biogas Wood Other Dung straw Coal Year fuel Mix Country Angola 2009 MICS/ Total 33% 1% 4% 0% 19% 43% 0% 0% 0% 62% 38% IBEP Rural 3.5% 0.3% 3.5% 0.0% 11.8% 79.9% 0.3% 0.0% 0.7% 92.7% 7.3% (2011)Urban 59.5% 1.7% 4.1% 0.0% 25.2% 8.0% 0.2% 0.0% 1.3% 34.7% 65.3% Benin 2012 DHS Total 5.9% 0.0% 0.4% 1.0% 25.7% 65.3% 0.6% 0.0% 1.1% 93.7% 6.3% Rural 0.4% 0.0% 0.1% 0.1% 7.6% 90.0% 0.8% 0.0% 1.0% 99.5% 0.5% Urban 12.9% 0.1% 0.8% 2.1% 48.4% 34.1% 0.2% 0.0% 1.4% 86.2% 13.8% Botswana 2006 WHO Total 45.8% 7.2% 3.2% 0.1% 0.0% 43.4% 0.0% 0.1% 0.1% 43.8% 56.2% Rural 36.7% 4.5% 1.8% 0.1% 0.0% 56.6% 0.0% 0.2% 0.1% 57.0% 43.0% Urban 71.1% 14.8% 7.2% 0.1% 0.0% 6.6% 0.0% 0.0% 0.2% 6.9% 93.1% Burkina 2010 DHS Total 5.3% 0.0% 0.0% 0.0% 4.3% 87.5% 0.0% 0.0% 2.9% 94.7% 5.3% Faso Rural 0.8% 0.0% 0.0% 0.0% 1.3% 95.4% 0.0% 0.0% 2.5% 99.2% 0.8% Urban 19.0% 0.0% 0.0% 0.0% 13.2% 63.6% 0.0% 0.0% 4.2% 81.0% 19.0% Burundi 2010 DHS Total 0.2% 0.0% 0.0% 0.0% 8.3% 84.7% 5.5% 0.0% 1.3% 99.8% 0.2% Rural 0.0% 0.1% 0.0% 0.0% 2.2% 91.2% 5.9% 0.0% 0.6% 99.9% 0.1% Urban 0.5% 0.8% 0.0% 0.0% 70.0% 20.0% 1.1% 0.0% 7.6% 98.7% 1.3% Cameroon 2011 DHS Total 18.3% 0.1% 3.8% 0.3% 2.4% 70.5% 1.3% 0.0% 3.3% 77.8% 22.2% Rural 1.6% 0.0% 0.9% 0.0% 1.3% 92.5% 1.7% 0.0% 2.0% 97.5% 2.5% Urban 34.3% 0.2% 6.6% 0.6% 3.4% 49.3% 1.1% 0.0% 4.5% 58.9% 41.1% Cape Verde 2006 WHO Total 63.7% 0.0% 0.0% 0.0% 0.0% 33.8% 0.0% 0.0% 2.4% 36.3% 63.7% Rural 27.6% 0.0% 0.0% 0.0% 0.0% 70.7% 0.0% 0.0% 1.7% 72.4% 27.6% Urban 86.0% 0.0% 0.0% 0.0% 0.0% 11.1% 0.0% 0.0% 2.9% 14.0% 86.0% Central 2010 MICS Total 0.1% 0.1% 0.0% 0.2% 2.6% 96.3% 0.0% 0.0% 0.7% 99.8% 0.2% African Rural 0.0% 0.0% 0.0% 0.2% 0.4% 98.8% 0.0% 0.0% 0.6% 100.0% 0.0% Republic Urban 0.1% 0.2% 0.1% 0.3% 6.1% 92.5% 0.0% 0.0% 0.8% 99.7% 0.3% Chad 2010 MICS Total 1.6% 0.1% 0.3% 0.0% 2.9% 92.9% 0.6% 0.5% 1.1% 98.0% 2.0% Rural 0.0% 0.0% 0.0% 0.0% 1.1% 96.9% 0.6% 0.6% 0.8% 100.0% 0.0% Urban 7.0% 0.4% 1.3% 0.1% 8.7% 80.1% 0.5% 0.2% 1.7% 91.3% 8.7% Comoros 2011 DHS Total 4.0% 0.5% 18.3% 0.2% 1.6% 73.4% 0.2% 0.0% 1.8% 77.2% 22.8% Rural 1.6% 0.3% 5.5% 0.2% 1.2% 89.2% 0.2% 0.0% 1.8% 92.6% 7.4% Urban 8.7% 1.0% 43.8% 0.2% 2.3% 41.7% 0.3% 0.0% 2.0% 46.5% 53.5% Congo 2012 DHS Total 15.0% 1.2% 11.4% 0.0% 32.8% 37.8% 0.3% 0.0% 1.5% 72.4% 27.6% (Brazzaville) Rural 1.4% 1.1% 3.6% 0.0% 11.3% 81.7% 0.0% 0.0% 0.9% 93.9% 6.1% Urban 22.9% 1.3% 16.0% 0.0% 45.3% 12.2% 0.4% 0.0% 1.9% 59.8% 40.2% Côte 2012 DHS Total 14.9% 0.0% 0.0% 0.0% 17.8% 60.0% 0.0% 0.0% 7.3% 85.1% 14.9% D’Ivoire Rural 0.9% 0.0% 0.0% 0.0% 5.4% 86.9% 0.0% 0.0% 6.8% 99.1% 0.9% Urban 31.8% 0.0% 0.0% 0.0% 32.8% 27.6% 0.0% 0.0% 7.8% 68.2% 31.8% Democratic 2007 DHS Total 0.0% 3.7% 0.1% 0.0% 24.9% 71.2% 0.0% 0.0% 0.1% 96.2% 3.8% Republic of Rural 0.0% 0.0% 0.0% 0.0% 11.2% 88.8% 0.0% 0.0% 0.1% 100.0% 0.0% the Congo Urban 0.0% 10.9% 0.3% 0.0% 52.0% 36.2% 0.6% 0.0% 0.0% 88.8% 11.2% Djibouti 2006 National Total 4.9% 0.6% 80.6% 0.0% 8.7% 3.7% 0.0% 0.0% 1.5% 13.9% 86.1% Census Rural 4.2% 0.6% 70.7% 0.0% 14.6% 7.7% 0.0% 0.0% 2.2% 24.5% 75.5% / WHO Urban 5.1% 0.6% 83.6% 0.0% 6.9% 2.5% 0.0% 0.0% 1.3% 10.7% 89.3% Equatorial 2012 DHS Total 17.9% 1.3% 34.7% 0.3% 1.0% 42.2% 0.1% 0.0% 2.5% 46.1% 53.9% Guinea Rural 5.3% 0.9% 17.9% 0.3% 1.8% 72.2% 0.2% 0.2% 1.2% 75.9% 24.1% Urban 32.6% 1.8% 54.4% 0.2% 0.0% 7.3% 0.0% 0.1% 3.6% 11.2% 88.8% 137 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Ag. waste/ Electricity LPG/LNG/ Solid fuel Kerosene Charcoal Modern Source biogas Wood Other Dung straw Coal Year fuel Mix Country Eritrea 2009 EPHS Total 3.0% 0.0% 16.0% 0.0% 10.0% 60.0% 0.0% 10.0% 1.0% 81.0% 19.0% (2010) Rural 0.5% 0.0% 7.0% 0.0% 10.0% 71.0% 0.0% 11.0% 0.5% 92.5% 7.5% Urban 13.7% 2.0% 54.4% 0.0% 10.0% 13.1% 0.0% 5.7% 1.1% 30.0% 70.0% Ethiopia 2011 DHS Total 0.3% 0.7% 2.4% 0.0% 7.7% 77.9% 2.0% 7.0% 2.0% 96.6% 3.4% Rural 0.0% 0.0% 0.1% 0.0% 1.2% 87.3% 2.2% 8.3% 0.9% 99.9% 0.1% Urban 1.1% 2.9% 10.1% 0.0% 29.9% 46.2% 1.3% 2.8% 5.7% 85.9% 14.1% Gabon 2012 DHS Total 79.0% 0.3% 0.9% 0.0% 1.4% 13.1% 0.0% 0.0% 5.3% 19.8% 80.2% Rural 35.3% 0.1% 0.7% 0.0% 4.6% 57.8% 0.0% 0.0% 1.5% 63.9% 36.1% Urban 87.7% 0.4% 0.9% 0.0% 0.8% 4.4% 0.0% 0.0% 5.8% 11.0% 89.0% Gambia, The 2010 MICS Total 0.7% 0.1% 0.0% 0.0% 12.0% 85.2% 0.4% 0.0% 1.6% 99.2% 0.8% Rural 0.0% 0.0% 0.0% 0.0% 0.6% 98.3% 0.3% 0.0% 0.8% 100.0% 0.0% Urban 1.7% 0.0% 0.1% 0.0% 25.2% 70.1% 0.4% 0.0% 2.5% 98.2% 1.8% Ghana 2011 MICS Total 17.4% 0.3% 0.1% 0.0% 29.4% 50.0% 1.0% 0.0% 1.8% 82.2% 17.8% Rural 3.6% 0.0% 0.0% 0.0% 15.6% 77.0% 2.9% 0.0% 0.9% 96.4% 3.6% Urban 31.9% 0.6% 0.3% 0.0% 44.2% 21.2% 0.4% 0.0% 1.4% 67.2% 32.8% Guinea 2012 DHS Total 0.1% 0.2% 0.0% 0.0% 28.6% 68.6% 0.0% 0.0% 2.5% 99.7% 0.3% Rural 0.0% 0.0% 0.0% 0.0% 7.0% 91.7% 0.0% 0.0% 1.3% 100.0% 0.0% Urban 0.2% 0.6% 0.1% 0.0% 72.9% 21.1% 0.0% 0.0% 5.1% 99.1% 0.9% Guinea- 2010 MICS Total 0.6% 0.0% 0.0% 0.0% 30.8% 67.7% 0.8% 0.1% 0.0% 99.4% 0.6% Bissau Rural 0.0% 0.0% 0.0% 0.0% 3.0% 96.7% 0.1% 0.1% 0.1% 100.0% 0.0% Urban 1.3% 0.0% 0.0% 0.0% 69.5% 27.4% 1.7% 0.0% 0.1% 98.7% 1.3% Kenya 2009 DHS Total 4.8% 0.3% 4.5% 0.9% 15.8% 71.9% 1.5% 0.0% 0.3% 90.4% 9.6% Rural 0.9% 0.0% 0.6% 1.1% 8.7% 87.0% 1.6% 0.0% 0.1% 98.5% 1.5% Urban 21.2% 1.4% 20.9% 0.0% 45.2% 9.4% 1.0% 0.0% 0.9% 56.5% 43.5% Lesotho 2009 DHS Total 20.5% 6.1% 7.4% 0.2% 0.0% 49.4% 7.4% 7.9% 1.1% 66.0% 34.0% Rural 10.2% 1.7% 4.1% 0.2% 0.0% 71.8% 1.0% 10.1% 0.9% 84.0% 16.0% Urban 53.1% 20.1% 17.7% 0.1% 0.0% 7.0% 0.0% 1.1% 0.9% 9.1% 90.9% Liberia 2007 DHS Total 0.1% 0.0% 0.1% 0.0% 39.4% 59.3% 0.0% 0.0% 1.2% 99.9% 0.1% Rural 0.0% 0.0% 0.0% 0.0% 13.1% 86.2% 0.0% 0.0% 0.8% 100.0% 0.0% Urban 0.2% 0.0% 0.1% 0.0% 85.3% 12.6% 0.0% 0.0% 1.8% 99.7% 0.3% Madagascar 2011 EIPMD / Total 0.6% 0.1% 0.0% 1.0% 21.4% 75.9% 0.0% 0.0% 1.1% 99.4% 0.7% MICS Rural 0.1% 0.1% 0.0% 0.0% 12.7% 84.9% 0.0% 2.0% 0.2% 99.8% 0.2% Urban 2.6% 0.7% 0.1% 0.3% 74.5% 20.4% 0.0% 1.4% 0.0% 96.6% 3.4% Malawi 2010 DHS Total 0.0% 1.6% 0.0% 0.0% 10.4% 86.4% 1.5% 0.0% 0.1% 98.4% 1.6% Rural 0.0% 0.2% 0.0% 0.0% 3.0% 95.0% 1.7% 0.0% 0.1% 99.8% 0.2% Urban 0.0% 8.9% 0.1% 0.1% 49.4% 40.7% 0.5% 0.0% 0.3% 91.0% 9.0% Mali 2006 DHS Total 0.4% 0.0% 0.0% 0.0% 15.9% 80.2% 0.0% 2.2% 1.3% 99.5% 0.5% Rural 0.0% 0.0% 0.0% 0.0% 5.3% 91.2% 0.0% 2.6% 0.9% 99.9% 0.1% Urban 1.4% 0.1% 0.0% 0.0% 40.0% 55.2% 0.0% 1.1% 2.3% 98.6% 1.4% Mauritania 2011 MICS Total 38.2% 1.1% 0.0% 0.0% 19.5% 40.3% 0.0% 0.0% 0.9% 60.7% 39.3% Rural 18.1% 0.2% 0.0% 0.0% 15.0% 65.6% 0.0% 0.0% 1.1% 81.7% 18.3% Urban 65.5% 2.3% 0.0% 0.0% 25.7% 5.8% 0.0% 0.0% 0.7% 32.2% 67.8% Mozambique 2011 DHS Total 2.6% 0.8% 0.0% 1.0% 15.0% 80.0% 0.0% 0.0% 0.6% 96.6% 3.4% Rural 0.3% 0.1% 0.0% 0.2% 3.4% 95.4% 0.0% 0.0% 0.6% 99.6% 0.4% Urban 8.0% 2.5% 0.1% 2.8% 42.2% 44.2% 0.0% 0.0% 0.2% 89.4% 10.6% Namibia 2006 DHS Total 7.2% 34.2% 0.3% 0.1% 0.6% 54.9% 0.0% 0.2% 2.6% 58.3% 41.7% Rural 3.5% 5.9% 0.1% 0.1% 0.9% 88.8% 0.1% 0.4% 0.2% 90.5% 9.5% Urban 11.5% 67.1% 5.4% 0.0% 0.1% 15.5% 0.0% 0.0% 0.4% 16.0% 84.0% 138 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Modern fuel Ag. waste/ Electricity LPG/LNG/ Solid fuel Kerosene Charcoal Source biogas Wood Other Dung straw Coal Year Mix Country Niger 2012 DHS Total 0.8% 0.1% 0.0% 0.1% 1.5% 86.2% 7.3% 1.9% 2.1% 99.1% 0.9% Rural 0.0% 0.0% 0.0% 0.0% 0.4% 86.9% 8.5% 2.3% 1.9% 100.0% 0.0% Urban 5.0% 0.5% 0.0% 0.5% 7.1% 82.7% 1.2% 0.0% 3.0% 94.5% 5.5% Nigeria 2013 DHS Total 2.3% 0.4% 25.5% 0.3% 3.2% 63.7% 1.8% 0.1% 2.7% 71.8% 28.2% Rural 0.5% 0.2% 8.7% 0.0% 1.6% 83.3% 3.1% 0.1% 2.5% 90.6% 9.4% Urban 4.6% 0.7% 47.6% 0.7% 5.3% 37.9% 0.2% 0.0% 3.0% 47.1% 52.9% Rwanda 2010 DHS Total 0.1% 0.1% 0.1% 0.3% 9.6% 88.7% 0.0% 0.1% 1.1% 99.7% 0.3% Rural 0.0% 0.0% 0.1% 0.1% 3.0% 95.7% 0.0% 0.2% 1.0% 99.9% 0.1% Urban 0.3% 0.3% 0.5% 1.6% 50.1% 45.4% 0.0% 0.0% 1.8% 98.9% 1.1% Senegal 2011 DHS Total 31.6% 1.2% 0.0% 0.0% 11.8% 52.5% 0.0% 1.4% 1.5% 67.2% 32.8% Rural 5.1% 0.5% 0.0% 0.0% 8.2% 82.8% 0.0% 2.7% 0.7% 94.4% 5.6% Urban 59.3% 2.0% 0.0% 0.0% 15.5% 20.8% 0.0% 0.1% 2.3% 38.7% 61.3% Sierra 2010 MICS Total 0.1% 0.0% 0.0% 0.3% 0.1% 14.0% 0.0% 83.3% 2.3% 99.9% 0.1% Leone Rural 0.0% 0.0% 0.0% 0.0% 0.0% 2.5% 0.0% 97.1% 0.4% 100.0% 0.0% Urban 0.1% 0.0% 0.0% 0.0% 0.0% 38.7% 0.0% 59.9% 1.3% 99.9% 0.1% Somalia 2005 MICS Total 0.0% 0.1% 0.2% 0.0% 33.1% 66.4% 0.1% 0.0% 0.1% 99.7% 0.3% Rural 0.0% 0.0% 0.1% 0.0% 8.0% 91.7% 0.1% 0.0% 0.1% 99.9% 0.1% Urban 0.1% 0.2% 0.3% 0.0% 79.1% 20.2% 0.0% 0.0% 0.1% 99.4% 0.6% South Africa 2007 National Total 2.0% 66.4% 14.8% 1.2% 0.0% 15.2% 0.0% 0.2% 0.2% 16.8% 83.2% Census Rural 1.5% 35.0% 30.0% 0.0% 0.0% 28.0% 0.0% 5.0% 0.5% 33.5% 66.5% / WHO Urban 2.5% 85.0% 5.0% 2.0% 0.0% 5.6% 0.0% 0.0% 0.0% 7.5% 92.5% South 2010 MICS Total 0.3% 0.0% 0.1% 0.0% 14.0% 81.4% 3.4% 0.2% 0.6% 99.6% 0.4% Sudan Rural 0.1% 0.0% 0.1% 0.0% 7.2% 88.0% 3.9% 0.3% 0.4% 99.8% 0.2% Urban 1.1% 0.0% 0.2% 0.0% 34.4% 61.6% 2.1% 0.1% 0.5% 98.7% 1.3% Sudan 2006 SHHS/ Total 8.1% 0.1% 0.5% 18.0% 2.0% 70.0% 0.7% 0.7% 0.0% 91.3% 8.7% MICS Rural 3.0% 0.0% 0.0% 15.0% 1.0% 79.0% 1.0% 1.0% 0.0% 97.0% 3.0% Urban 18.5% 0.2% 1.5% 24.0% 4.0% 51.8% 0.0% 0.0% 0.0% 79.8% 20.2% Swaziland 2010 MICS Total 10.6% 16.8% 2.5% 0.2% 0.3% 68.7% 0.3% 0.1% 0.5% 70.1% 29.9% Rural 5.9% 6.9% 0.7% 0.1% 0.2% 85.9% 0.0% 0.2% 0.1% 86.5% 13.5% Urban 26.4% 49.6% 8.8% 0.3% 0.6% 13.8% 0.0% 0.0% 0.5% 15.2% 84.8% Tanzania 2010 DHS Total 0.3% 1.1% 2.7% 0.0% 20.8% 73.9% 0.3% 0.0% 0.9% 95.9% 4.1% Rural 0.0% 0.2% 0.4% 0.0% 6.3% 92.4% 0.3% 0.0% 0.4% 99.4% 0.6% Urban 0.9% 3.8% 9.4% 0.0% 62.2% 20.7% 0.3% 0.0% 2.7% 85.9% 14.1% Togo 2010 MICS Total 2.0% 0.1% 0.3% 0.0% 38.5% 58.6% 0.1% 0.0% 0.4% 97.6% 2.4% Rural 0.1% 0.0% 0.1% 0.0% 14.5% 84.7% 0.6% 0.0% 0.1% 99.9% 0.1% Urban 5.3% 0.3% 0.5% 0.0% 78.3% 15.3% 0.1% 0.0% 0.2% 93.9% 6.1% Uganda 2011 DHS Total 0.7% 0.3% 1.1% 0.0% 22.8% 72.5% 0.2% 0.0% 2.4% 97.9% 2.1% Rural 0.0% 0.1% 0.3% 0.0% 12.4% 85.3% 0.2% 0.0% 1.7% 99.6% 0.4% Urban 4.3% 1.3% 4.3% 0.0% 67.8% 16.9% 0.0% 0.0% 5.4% 90.1% 9.9% Zambia 2007 DHS Total 0.0% 14.5% 0.0% 0.2% 25.0% 60.0% 0.0% 0.0% 0.3% 85.5% 14.5% Rural 0.0% 1.8% 0.0% 0.0% 10.2% 87.9% 0.0% 0.0% 0.1% 98.2% 1.8% Urban 0.0% 38.5% 0.0% 0.6% 53.1% 7.6% 0.0% 0.0% 0.2% 61.4% 38.6% Zimbabwe 2011 DHS Total 0.2% 28.4% 1.9% 0.0% 0.1% 68.9% 0.0% 0.0% 0.5% 69.5% 30.5% Rural 0.0% 5.6% 0.2% 0.1% 0.1% 93.9% 0.0% 0.0% 0.1% 94.2% 5.8% Urban 0.4% 73.2% 5.2% 0.0% 0.2% 19.8% 0.0% 0.0% 1.2% 21.2% 78.8% 139 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Appendix 6: Methodology for Fuel Market Sizing and Forecast The value of the fuel market in 2010 is based on the estimated fuel mix, average SSA fuel prices, and average annual per-household fuel consumption for users of “primary” fuels. The logic of the model is that households using “primary” fuels (as reflected in fuel mix data) purchase a standard amount of fuel and pay the prevailing average retail market price. Data Sources and Methodology for 2010 Market Sizing Fuel mix: The SSA regional fuel mix is derived from the regional fuel mix analysis and draws on surveys for all 45 SSA countries (see Appendixes 4 and 5). Fuel prices: Average 2010 fuel unit prices draw on a proprietary database of LPG, charcoal, kerosene, and electricity for the SSA region derived from press searches and pre-existing databases, such as the 2000–9 kerosene price database from Lighting Africa (2012), the UPDEA (2009) survey of electricity prices across the continent, and Data Monitor Statistical Review of LPG and WLPGA for LPG retail prices. Where possible, the prices are weighted by country fuel volumes (e.g., for charcoal, LPG, and electricity), to get the true average regional price. For those fuels that may be freely collected (e.g., dung, crop waste, firewood), the fuel collector vs. purchaser share is estimated based on country-level surveys (e.g., 12 country data points on the share of firewood-using households purchasing wood). Fuel-use volumes: The average annual per-household fuel consumption data from Schlag and Zuzarte (2008) and the World Bank (2011b) assumes a standard household cooking “diet” of 320 MJ per month per household using a fuel as its primary cooking source, which equates to 2.5 meals per day for a household of 5. The average fuel consumption is computed for each major stove type (e.g., traditional, basic, intermediate, advanced for wood), using the average fuel savings rate for each fuel. Total fuel consumption volume calculations take into account the baseline penetration of each stove type. The size of the “secondary” cooking fuel market is estimated separately — i.e., fuel use by households who use a different fuel as their primary cooking energy (e.g., LPG use by households who primarily cook with biomass). The secondary market is estimated based on a few country proxies (e.g., Kojima et al. 2011 data on multifuel use for Kenya). Total cooking fuel consumption volumes for the region have been validated by triangulating the results with other aggregate regional fuel consumption databases (e.g., FAO 2010 data for wood and charcoal, WLPGA for LPG volumes, South Africa Coal Association for SSA coal volumes). Methodology for 2020 Fuel Market Forecast The 2020 fuel market forecast utilizes 2020 fuel mix data from the regional fuel mix analysis (Appendix 5), projects stove penetration rates and associated changes in average fuel volumes per household from the ICS penetration forecast model (Appendix 9), and projects fuel prices using historical price trends from SSA fuel data series data for 2000–10. All fuel prices are discounted by the global Consumer Price Index inflation rate (about 2.4%) to ensure comparability with 2010 data. Tables 6.1 and 6.2 show key fuel volume, price, and price growth rate assumptions. 140 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Table 6.1: 2010 Fuel market sizing Fuel type Share of SSA Average per HH Cooking fuel Cost Market size households annual fuel use annual volume (US$ per unit) (US$ billions) (100% = 854 mil) (primary­—total) Wood 67% 1745 kg 200–207 mn tons 0.10 6.2 (32% purchased)1 Charcoal 13% 819 kg 18–22 mn tons 0.27 5.8 Dung 2% 2200 kg 6.7–8.3 mn tons 0.07 0.06 (10% purchased)2 Coal 1% 824 kg 1.6–1.8 mn tons 0.10 0.18 LPG 5% 150 kg 1.1–1.2 mn tons 1.57 2.0 Kerosene 7% 200 liter 2.2–2.5 mn liters 1.00 2.5 Electricity 5% 3232 kWh 30–33 tWh 0.10 3.3 Natural gas 0.22% 6.6 mmBTU 2.5–2.7 mmBTU 4.50 0.01 1 12 SSA country data points on firewood purchasing behavior; includes both exclusive and partial firewood purchasers. 2 Data based on interview estimates for Ethiopia. Table 6.2: Key assumptions for fuel prices and household consumption Fuel Fuel use per household (2010) Fuel prices (2010) Wood Traditional stove = 1800 kg (WB 2010) based on US$0.1 price, assuming 30% of charcoal costs based 14.5–16 MJ/kg and a 320-MJ diet; legacy stove = on average charcoal-to-wood relationship in 8 SSA 10% fuel savings, basic KCJ-type ICS = 30% fuel countries and average charcoal price of 0.30 savings, rocket ICS and ACS = 50% savings Charcoal Traditional stove = 880 kg (FAO 2011 = 700 kg, WB US$0.27/kg average charcoal price for a standard 2010 = 888 kg, Sullivan and Barnes 2006 = 830 kg); charcoal bag; average prices weighted for charcoal basic charcoal ICS like KCJ = 25% savings, advanced consumption volumes for 22 countries in SSA; rural charcoal ICS = 50% savings area prices 50% of urban; poor purchasing small bags (1–2 kg) pay 45% premium on average Dung Traditional stove = 1000 kg; 1200 kg in Ethiopia US$0.07/kg (price in Ethiopia, key SSA dung market, Tigray region (Mekonnen & Kohlin 2008) based on press reports) Coal Traditional stove = 880 kg, equivalent to 5 GJ of US$0.1/kg based on global ~US$100/ton energy (reported use in S. Africa closer to 2,000 per bituminous coal prices HH but includes water and room heating) LPG 154 kg per HH for 320 MJ (SEI 2008), WB 2010 has US$1.57/kg average retail price based on volume- 156 kg per HH; equal to 13-kg cylinder per month based weighting of LPG prices in 20 SSA countries Kerosene 204 kg per HH for 320 MJ (SEI 2008); WB (2010) US$1/liter on average across SSA (Lighting Africa assumes 180 kg per month, Sullivan and Barnes 2012) (2006) assumes 210 kg per month for 5 MJ Electricity 3232 kWh per year (assumes 3.6 MJ per kW US$0.1/kWh on average across SSA, weighed for according to FAO) the 5–6 countries with 90% of all electric stove use Natural gas 6.6 mmBTU = 3.6 mmBTU required annually divided by 55% fuel efficiency divided by 1 mmBTU stove output at 100% efficiency 141 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Appendix 7: Methodology for Analyzing Emissions from Solid-Fuel Cooking To assess the environmental and climate change impacts of solid-fuel reliance in Africa, the report authors developed a bottom-up inventory of the GHG and black carbon (BC) emissions resulting from charcoal production as well as solid-fuel cooking, using all common solid-fuel stove types. The analysis does not include emissions from kerosene stoves. The analysis has involved (1) identifying common emission ranges (grams per unit of fuel used) for key gases and particles released from incomplete fuel combustion for all common types of SSA stoves, (2) converting emissions to CO2 equivalents using a 100-year global warming potential (GWP-100) conversion factor, (3) applying emissions to the volume of fuel burned by each type of stove in Africa, and (4) cross-checking the aggregated GHG Kyoto emission and BC accounting with existing inventories of global emissions. Key stove types considered include traditional wood stoves, basic efficient wood ICS (e.g., ceramic wood stoves), intermediate wood ICS/rocket stoves, traditional charcoal stoves, basic efficient charcoal stoves (e.g., KCJ), and unvented coal stoves. The report also assesses the emissions of LPG stoves, advanced wood ICS (fan gasifier), and advanced charcoal ICS (e.g., Envirofit 4400), to develop a baseline for emissions abatement in the case that households switch to clean (or cleaner) technologies. For CO2 emissions, the report assumes 50–90% fNRB (nonrenewability ratio) for charcoal, 10–90% fNRB for wood, 0% fNRB for dung and crop waste, and 100% fNRB for such fossil fuels as LPG and coal. Detailed calculations are available upon request from the authors. Key assumptions and the results of the analysis are shown in Tables 7.1 and 7.2. Table 7.1: GWP-100 weighting for calculating CO2 equivalents of greenhouse gas emissions PIC GHG CO2 multipliers Source CO2 1 CH4 25 UNDP 2000/Smith (25)x; Bond et al. 2013 (21x); IPCC 2007 (25x) CO 2 UNDP 2000 NMHC 11 UNDP 2000 = 11; Bond et al. 2013 (12x); IPCC 2007 (3.4x) N20 285 UNDP 2000/Smith = 261; Bond et al. 2013 = 296; Solomon et al. 2007 = 298 PM 67 Computed - BC (EC) 460 Reynolds and Kandlikar (2008) = 455; 460–2020 range (Berkeley Air Monitoring Group 2010); 1500–2220 range in Jacobson 2010 using GWP-100 - OC –30 50 to –30 range (Berkeley Air Monitoring Group 2010) Sources: Multiple emission inventories; Dalberg analysis. 142 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Table 7.2: Emission factors for common SSA stove/kiln types (grams of emissions per kg of fuel burned) Basic charcoal Wood rocket1 Charcoal kiln6 combustion Basic wood Traditional Traditional Dung/crop LPG stove2 wood1,2,3,4,5 of internal waste2,3,4,5 Wood fan Particles charcoal stove2,3,4 gasifier1 ICS1,3,4 Coal2 ICS7 CO2 total 1370–1688 1370–1688 1519 1500 1045–1302 2260–2410 2394–2543 685 841 1800 CO2 non- 137–169 137–169 152 150 0 1140 1200 685 841 900 renewable CO 39–70 74–79 70 5–6 39.9–65.6 110–275 270–350 30.3 16 225 CH4 3.8–8.0 2.5–4.0 3.9 n/a 4.5–10.5 2.4–18 14–15 7.7 1 44.6 N20 0.018 n/a n/a n/a 0.05–0.3 n/a n/a n/a n/a 0.15 NMHC 2.4–9.4 1.6–12.6 5.1 n/a 8.5–24.2 0.4–10.5 30–53 2.4 154 92.6 PM2.5 3.2–9.5 n/a 12.4 0.3 3–6.3 0.4–2.4 14–16 8.7 89 30.4 EC/BC 1.5 n/a 1.9 n/a 0.2–0.6 0.07 n/a 4.4 92 5.47 OC –4 n/a –12.5 n/a n/a –0.03 n/a 3.1 –3 16.0 (1) USAID (2011, 2012); (2) Grieshop et al. (2011); (3) UNDP (2000); (4) WHO (2006); (5) Venkataraman (2010); Pennise et al. (2001); Berkeley Air Monitoring Group 2010. Source: Dalberg analysis. 143 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Appendix 8: Customer Segmentation Methodology To facilitate market analysis, this report relies on a rough segmentation of fuel users across the regions of SSA (East, West, Southern, Central) for all major fuel types (wood, charcoal, kerosene, electricity, LPG, and others) by three income levels (low = under BoP 500, medium = BoP 500–1,500, high = BoP 1,500+) and fuel procurement approach (purchasing vs. collecting). The raw data generated by this analysis are used to further subdivide the SSA consumer into 7 distinct segments, which are then profiled in the report. The methodology and data sources for the analysis are presented in Tables 8.1 through 8.4.: Table 8.1: Fuel mix from fuel-use database (45 SSA countries) Market segmentation East Africa West Africa Central Africa Southern Africa Total Electricity 1,399,005 927,485 4,610,259 32,950,497 39,887,247 LPG 4,554,059 15,220,581 3,278,450 11,343,607 34,396,697 Natural gas 1,110,372 42,027 1,026 423,315 1,576,740 Biogas 335,434 8,383 61,585 35,000 440,402 Kerosene 5,952,275 35,086,337 1,252,018 2,049,654 44,340,284 Urban Coal 3,530,923 673,184 69,034 651,771 4,924,912 Charcoal 29,855,718 28,276,351 22,629,158 8,598,156 89,359,383 Wood 21,237,696 55,747,318 22,309,760 7,917,674 107,212,448 Dung 544,789 77,891 544,166 6,411 1,173,258 Crop waste 276,192 625,051 2,019 11,580 914,842 Other 1,252,991 2,062,523 116,742 202,023 3,634,278 Electricity 140,009 208,427 13,428 7,570,528 7,932,391 LPG 1,903,597 1,713,190 158,819 1,403,208 5,178,814 Natural gas 7,490 28,222 0 21,152 56,864 Biogas 0 2,143 1,901 67,801 71,844 Kerosene 902,575 6,515,378 203,473 5,870,571 13,491,997 Rural Coal 4,716,402 363,648 10,718 15,596 5,106,364 Charcoal 11,814,954 14,118,161 3,174,326 3,580,420 32,687,861 Wood 201,848,054 152,737,537 35,515,242 55,979,166 446,079,999 Dung 6,807,348 984,798 16,155 1,198,213 9,006,515 Crop waste 2,421,688 1,261,853 9,091 232,912 3,925,544 Other 1,183,113 1,048,964 34,432 280,512 2,547,021 Total 301,794,684 317,729,452 94,011,801 140,409,767 853,945,705 144 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Figure 8.1: Average income mix by fuel type (10 SSA countries) Average income mix by fuel type (10 SSA countries) <1% 2% 4% 9% 15% 37% 43% 62% BoP 1,500 59% 55% 35% 3% Wood Charcoal LPG Kerosene Electricity Table 8.2: Subregional population by BoP tier (10 countries) Subregion Urban Rural Low Middle High Low Middle High East Africa 2.0% 5.7% 9.8% 20.8% 47.6% 14.1% West Africa 24.5% 28.2% 5.1% 25.0% 16.1% 1.1% Southern Africa 2.5% 12.0% 23.2% 32.5% 25.7% 4.1% Central Africa 18.1% 21.0% 3.4% 38.0% 18.8% 0.7% Figure 8.2: Wood purchaser vs. collector segmentation (12 countries) Purchasing (~30%) vs. collecting: (~70%) Purchasing rural (20% vs. urban 75%) Purchasing low (19%), middle (45%), high (85%) Sources: Fuel-purchasing behavior data across 12 countries globally (different data sources); analysis by Dalberg. 1. Regional fuel segmentation: Regional fuel mix data for 2010 (see Appendix 5). 2. Regional income segmentation: A consistent (absolute) income segmentation for each African region is derived from Hammond et al. (2007) income segmentation survey data, which allows us to segment the rural and urban population in each region into BoP income bands (80% penetration of Kenya Ceramic Jiko (US$4–8) stoves in such cities as Nairobi. In contrast, the very poorest in such low-income markets as Ethiopia are unable to afford even very-low-cost stoves. For example, an in-depth 2011 market feasibility study of a US$4–7 Mirt injera improved stove in southern Ethiopia suggested that such a product would be absolutely unaffordable to 5–10% 160 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report of the urban and 20–30% of the rural population, even in the presence of consumer credit, installment purchase options, or partial subsidies (GIZ/MeGen Power 2011). Africa research by the Global LPG Partnership (e.g., see 2013 Kenya LPG market assessment at www.cleancookstoves.org) 109 and interviews with modern-fuel experts across the region conducted for this report all point to the primary importance of improved affordability for unlocking clean fuel market growth. 110 While it is impossible to draw a precise demand curve for the SSA market for every cooking technology, the basic premise is that clean cookstoves will be prohibitively expensive for the 50% of SSA households who currently earn less than US$1.25 per person per day, especially since many of these households currently pay nothing or nearly nothing for their stoves and fuels. See more detail in the affordability discussion later in the report. Broadcasting Board of Governors/Gallup surveys suggest that 57% of the SSA adult population in 2010 owned a mobile 111 phone handset; more recent data from the GSM Association suggest that penetration will exceed 70% by the end of 2014. 112 National energy survey data from DHS, LSMS, and MICS and national census data show modern-fuel stove (US$15–100) penetration of 17–18% for SSA; this report’s estimates for ICS uptake across the region show a penetration of up to 2% for intermediate ICS (US$15–30). These data suggest that at least 20% of households have paid more than US$15–20 in the past; adding basic ICS (6%), at least 25% of HH have paid for some form of improved or clean cooking appliance that they use as their primary stove. While there are no good data on secondary stove ownership, the best-guess estimates that are available (see note 32), suggest that secondary modern-fuel stove owners may be at maximum another 6–9% of the SSA population, for a grand total of up to a third (34%) of all SSA households owning a purchased (as opposed to home-built or three-stone fire) cookstove. 113 Shell Foundation, Room to Breathe Program (2007–09). Since the survey results are somewhat dated, projecting these numbers into 2013 with 5–7% inflation and income growth suggests that the share of consumers who can afford a US$30+ product could now be a good deal higher. On the other hand, income levels in many parts of the continent are much lower than in these three countries, so the evidence is still telling. Although average SSA handset costs are unknown and likely vary greatly by country, the literature and interviews suggest 114 that the average trends low (US$30–50) due to the introduction of low-cost (US$15–20) handsets over the past five years, the high share of very-low-cost “counterfeit” phones from low-quality providers, and extensive use of old and second-hand handsets across the region (see, e.g., Chabossou et al. 2009). 115 Applying average SSA prices with typical unimproved stoves, the annual cost of cooking all meals with LPG for a household of five (about US$260) is 40–50% higher than the cost of cooking all meals with purchased wood (US$180). The premium of ethanol fuel use (US$200–300) over purchased firewood cooking is comparable. The cost of charcoal cooking is roughly on a par with LPG on average, though the relationship varies dramatically by country and the lower costs of charcoal stoves and easier access to charcoal constrain fuelswitching from charcoal to LPG. 116 This estimate assumes that high-cost clean cookstoves are analogous to the average consumer durable in Africa and, therefore, are unlikely to see more uptake than the historical share of consumers who annually buy US$30+ consumer durables in countries, such as Kenya, Tanzania, and Uganda. This consumer segment roughly corresponds to the high- income (>BoP 1,500) consumer in this report’s segmentation model, which corresponds to 16% of the SSA population. 117 As one point of triangulation, the 450,000 renewable cooking fuel households. The source data for this information are listed in the notes and text that follow. 138 This figure includes roughly 20,000 fan-gasifier stoves utilized in market pilots or RCTs by Q1 2014; the balance of stoves are a variety of natural-draft gasifier stove models. Data on stove distribution are sourced by aggregating self-reported project/manufacturer data and then triangulated with interviews with peer/competitor firms and the limited publications available on the ACS sector; see, e.g., Roth et al. (2013). The estimate covers 15 ACS manufacturers, including Philips/ACE, BioLite, New Dawn Engineering, Peko Pe, ARTI Sampada, WorldStove, Awamu/ABE (Uganda); GreenTech (Gambia); and Aaron (Niger); 5 Star Stoves (South Africa); Wisdom Innovation, Kiwia, and Laustsen (Tanzania); mlc (Gambia); Arti Sampada. With the exception of a few demonstration models, very few of these stoves (<15,000) have been sold; the vast majority are models distributed as part of a range of commercial and noncommercial market pilots. The wide range on the estimated stove count is explained by uncertainty about the validity of stove sales reported by several of the ACS market participants. 139 These late 2013 data are from the Africa Biogas Partnership Programme, which is responsible for most of the biogas stoves installed in Africa today; additional self-reported data come from unaffiliated biogas project developers in Burundi, Lesotho, Rwanda, and Tanzania (e.g., SimGas). 140 Includes less than 50,000 Domestic CleanCook stoves distributed in a range of market pilots, primarily the now liquidated CleanStar Mozambique business in Mozambique (33,000 stoves); Project Gaia initiatives in Ethiopia, Madagascar, and Nigeria; an estimated 160,000–200,000 Green Energy and Biofuel “KIKE Green Cook” ethanol-gel fuel stoves in Nigeria, Ghana, Togo, and Cameroon; 45,000 ThermoSafe Energy ethanol-gel stoves in Nigeria; and an additional estimated 50,000–100,000 units in Malawi (SuperBlu), Kenya (Consumer’s Choice Ltd. “Moto Safi” and “Moto Poa” stoves), and South Africa (BioHeat/BioCorp, Greenheat, and ProtoEnergy ethanol stoves). All data are self-reported via manufacturer interviews and public statements. 141 This estimate is based on self-reported data on pellet production volumes (focused at retail market) from mid-sized to large producers in Kenya, Tanzania, Senegal, Rwanda, and Ethiopia, triangulated with recent African reports on the pellet/ briquette sector; see, e.g., Ferguson (2012) and EEP (2013). Data on SME briquette/pellet producers and social-sector artisanal pellet manufacturing projects come from the Legacy Foundation. 142 Self-reported data sourced from Solar Cookers International (SCI) and a range of other solar project promoters throughout Africa. 143 Self-reported data from Natural Balance (manufacturer of WonderBag retained-heat cooker) suggest that >600,000+ stoves were sold or distributed in South Africa, Kenya, and Rwanda by early 2013. 144 See note 7. 145 See the ICS penetration survey methodology in Appendix 9. 146 See methodological note 136 and Appendix 9 for more details on how these numbers were derived. 147 For most biomass stove technologies, the number of households owning a given stove type and the total number of stoves in use are identical. This is not so for portable basic ICS in Africa, where top-down survey data often only indicate the number of ICS households without tracking the number of stoves. Using rough estimates based on known ratios of basic ICS stoves disseminated to stoves owned per ICS-using household (e.g., 1.25–1.5 in Kenya), it is likely that the total number of basic ICS stoves, such as charcoal and wood jikos, is 30–50% higher than the number of households—i.e., bringing the basic ICS count up to a maximum of 8–9 million stoves in 2010–11. 163 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report 148 See the forthcoming report titled The State of the Global Clean and Improved Cooking Sector, jointly published by ESMAP/ WB and the Global Alliance for Clean Cookstoves. The estimate is based on bottom-up country analyses for more than 75 countries globally, accounting for more than 90% of solid-fuel users. 149 The precise number and proportion of three-stone fires in use in Africa are unknown, as such data are typically not captured in national surveys. Interviews with stove program managers across the region suggest that three-stone fire stoves constitute the absolute majority (70–85%) of all traditional stoves used as a primary household stove. The only traditional segment where commercially produced stoves are common is the unimproved metal charcoal stove market, with an estimated 10–15 million unimproved metal stoves used as a primary cookstove in Africa out of the 20 million African households that rely on charcoal as their main fuel (i.e., this is net of the estimated 5–7.5 million improved charcoal stoves in the market). Once secondary charcoal users are counted (50–100% of primary charcoal users based on the SSA fuel database), the real number of unimproved metal stoves in the market could be twice as large­ —i.e., a total directional estimate of 15–30 million traditional metal charcoal stoves. 150 See note 4; most “legacy” improved stoves in the ground in Africa are either unimproved stoves with chimneys or very basic home-built stoves that likely fall into ISO Tier 0–1 for fuel efficiency and Tier 0 for emissions. 151 While an aggregate figure for market growth is difficult to derive from fragmentary self-reported data, survey evidence from the Global Alliance for Clean Cookstoves (more than 700 members answering survey) suggests that cumulative clean and improved cooking market sales growth is likely very rapid. For instance, there was 74% annual growth in the number of stoves produced and tracked by the Alliance and its predecessors globally from 2003 to 2012, half of them in Africa, and more than 80% sales growth year-on-year for many individual producers reporting figures in both 2011 and 2012 (GACC 2013). Historical (2000–10) growth trends for primary-fuel use across SSA, based on an aggregation of national surveys for 45 SSA 152 countries, are 5% annual increase for LPG, 3.5% for LNG, 4.3% for electric cooking, and 0.7% for kerosene (reflecting a negative growth rate for kerosene use in the past 3–5 years). 153 See, for instance, detailed data showing the retrenchment of LPG fuel use in Senegal in recent years (Practical Action 2014)—a trend that was likely attended by a corresponding softening in the LPG appliance market. 154 See http://www.snvworld.org/en/regions/africa/news/fuelling-the-biogas-future-in-africa-abpp-secures-new-funding. For general ABPP project background, see www.africabiogas.org. 155 Pellet and briquette fuel businesses that fall into this category include Inyenyeri in Rwanda (www.inyenyeri.org); Africa Briquet Factory in Ethiopia (www.afribiomass.com); Abellon Clean Energy in Ghana (www.abelloncleanenergy.com); Emerging Cooking Solutions in Zambia (www.emerging.se); Greentech in Gambia (www.greentechgambia.com/); Mota Bombo pellet fuels (www.treetanz.com) and renewable charcoal dust briquettes by the East Africa Briquette Company (www.mkaabora.com/) in Tanzania; Chardust charcoal briquettes and FireBalls in Kenya (chardust-kenya.blogspot.com); 5 Star Stoves in South Africa (http://5starstoves.com/); Tassouma Briquettes (www.tassouma-briquettes.com/) in Côte d’Ivoire; and businesses like Green Bio Energy (www.greenbioenergy.org) and Eco Fuel Africa (ecofuelafrica.co.ug) in Uganda. 156 The estimate for chimney stoves draws on Africa-wide DHS/MICS national survey data aggregated by WHO; the data are problematic insofar as they are available only for 33 countries, are sometimes quite dated (2005–13), and may include what are effectively traditional stoves with chimneys attached. To develop a continent-wide estimate, “missing” data points were filled in through interviews with country stakeholders, subnational NGO surveys on stove prevalence, and in once instance (Rwanda) a national census survey (RBESS 2009). For enclosed mud/clay stoves, the estimate is partly drawn from data for 2009–11 for Ethiopia and anecdotal reports of hundreds of thousands of such stoves elsewhere in the continent. For conservatism, only the Ethiopia numbers have been used, but the total number of such stoves may be significantly higher. 157 For the geographic spread of the KCJ technology and its analogues, see Figure 36. More than 25 million African households used the technology in 2011—a figure that has increased significantly in recent years to more than 30 million African households based on report penetration figures in countries, such as Kenya, Senegal, Ethiopia, and Ghana. 158 The basic wood ICS segment covers a wide range of technologies, including fired-clay solutions (upesi in Kenya and Tanzania, opesi in Ethiopia, chitetezo mbaula in Malawi); ceramic or clay-lined metal wood stoves along the lines of the KCJ (e.g., centrafricain in Chad and Cameroon, mandeleo metal clad upesi in Kenya, sewa/teliman in Mali); cement/brick stoves (e.g., Ethiopia cement wood stoves, Malawi esperanza); and a range of all-metal wood stove designs in West Africa (e.g., roumdé in Burkina Faso, sakkanal in Senegal, nansu in Benin). This report’s estimate for the basic wood ICS segment is likely an underestimate, since the dissemination of stoves of this type is fragmented over several government programs, 5–10 major international NGOs, and dozens of local NGOs throughout the continent. With notable exceptions, such as the GIZ and EnDev programs, the governments of Rwanda and Ethiopia, and a few large local and international NGOs, data tracking is extremely poor. The estimate in this report relies on self-reported data from reputable programs and triangulation from country-level estimates captured in the Global Alliance for Clean Cookstoves’ market assessment reports and is likely an underestimate of the stoves currently in the market. 164 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report 159 Anecdotal reports of the decline of the legacy stove segment were universal in the interviews conducted with more than 100 stove market stakeholders across East and West Africa for this report. The (admittedly sparse) data on the segment from the WHO survey bears this out, with significant declines tracked for some countries (e.g., 8% chimney stove penetration in Malawi in the 2005–6 household survey and less than 2% penetration in 2010). 160 The acceleration in basic charcoal ICS production is reflected in survey numbers for countries, such as Kenya (i.e., showing continued growth in urban ICS penetration, even as that market is beginning to reach saturation); the data of sizable semi- industrial KCJ stove manufacturers from Kenya, Uganda, Senegal, and Ethiopia made available to the report team showing 15–60% annual sales growth; and the data of large-scale NGO (e.g., Enterprise Works) and government (e.g., Ethiopia Lakech stove) efforts. The growth shown in Figure 32 is a conservative estimate based on known numbers of units (adjusted for replacements and obsolescence) sold by major programs and manufacturers annually. 161 Data on the Burkina Fasa roumde adoption path are available in Bensch et al. (2013); anecdotal evidence from Kenya, Tanzania, and Uganda suggests that upesi-style stove sales are continuing to grow, but the extent to which these are replacement sales versus extension of the technology to new households is unclear in the absence of tracking, since major supporting programs, such as GIZ ProBEC, are no longer in place. 162 This analysis is based on (1) an aggregation of self-reported rocket stove sales by the top-30 industrial and semi-industrial manufacturers in Africa (or their carbon project development partners), and (2) the self-reported dissemination volumes from major national and NGO chimney/built-in rocket stove initiatives. It is quite possible that this analysis underestimates this segment’s rate of growth. The 2012 Results Report from the Global Alliance for Clean Cookstoves (GACC 20??), based on survey data from 744 Alliance members, showed that 1.6 million rocket stoves were sold and distributed in 2012 (about 37% of the 4.3 million stoves distributed to African consumers by survey respondents). Using a sales growth rate of roughly 50% annually, this corresponds to the more than 4 million stoves added to the market during 2012 and 2013, as captured by this report team’s data. Higher growth rates for the rocket stove sector are possible, however, based on anecdotal evidence from manufacturers and distributors. For instance, applying the Global Alliance 74% year-on-year historical growth rate in stove sales for the entire cooking sector overall would mean that the actual rocket stove penetration by the end of 2013 was even higher—a total of more than 8.5 million. This report uses the more conservative figure of 8 million that can be traced back to individual manufacturers, pending the release of new Global Alliance member survey data at the end of 2014. 163 Key developments of this sort include investments in production capacity in Kenya made by Envirofit, Burn Manufacturing, and EcoZoom, and exploratory measures by some of these companies and others to open manufacturing or subassembly facilities in other African countries to serve as potential subregional hubs. 164 In Rwanda, DelAgua Health has partnered with the Ministry of Health since 2012 to distribute free-of-charge household water treatment and EcoZoom wood rocket cookstoves to approximately 600,000 poor households (about 3 million people) throughout the country’s 30 districts. The pilot program was initiated in 2012, and mass-scale distribution was launched in mid-2014. For more details on the program and initial pilot results, see Barstow et al. (2014). 165 Government of Kenya 2006 Energy Policy; USAID and Winrock 2011; Dalberg analysis. 166 This result is based on the analysis of an Africa-wide database of DHS/MICS surveys (2005–13). The top-five markets for LPG are Angola, Cameroon, Côte d’Ivoire, Senegal, and South Africa. The six key markets for electric cooking, in rank order, are South Africa, Zimbabwe, the Democratic Republic of the Congo, Zambia, Namibia, and Ethiopia. Key markets for kerosene include Cameroon, Eritrea, Kenya, Nigeria, and South Africa. 167 These themes came across strongly in 2012–13 regional Global Alliance and World Bank ACCES consultations and are also well documented in the literature on the artisanal sector; see, e.g., Clough (2012). 168 While there are no robust quantitative data on stove quality, quality challenges—particularly for artisanally manufactured stoves—were a consistent theme in the report team’s interviews across a dozen SSA countries. Stakeholders in the Kenya stove market, for instance, reported that the average quality of Kenya Ceramic Jiko stoves in the field is low; the average stove life has declined over time to 1–1.5 years, as many producers use low-quality metal casings and liner materials; and average fuel efficiency levels (15–20%) are significantly below the KCJ technology’s potential (30–35%). 169 See Lighting Africa’s 2010 and 2012 solar portable industry reports at www.lightingafrica.org. 170 The World Bank estimates that 7 million people are employed in the charcoal value chain alone across SSA today, with aggregate charcoal-sector employment expected to reach 12 million people by 2030 (World Bank 2011b). Recent individual country studies estimate the involvement of 700,000 in the charcoal sector in Kenya, around 200,000 in Uganda, more than 100,000 in Malawi, and several hundred thousand supplying the needs of Dar es Salaam in Tanzania. Country-level estimates for the firewood trade are unavailable, but are likely to be on a comparable scale, particularly in West African nations with large urban firewood trade markets. Many of these jobs are part time and provide only low or moderate income, but a growing body of evidence points to the important livelihood benefits of woodfuel-sector employment for economically vulnerable segments of the SSA population. In aggregate, informal and formal woodfuel-sector employment, including part-time labor, could exceed 15 million individuals across the entire SSA region (Oksanen et al. 2003). 165 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report 171 See World Bank (2011b). 172 For REDD+, see http://www.un-redd.org/aboutredd/tabid/102614/default.aspx; for FIP, see https://www. climateinvestmentfunds.org/cif/node/5. 173 One successful example is the Community-Based Woodfuel Production (CBWP) project in Senegal; covering 380,000 hectares of forest, it is supported by the World Bank and promoted as part of the PROGEDE program. Other countries that have established plans for sustainable forest management include Benin, with a target of covering 600,000 hectares; Mali, where 1.4 million hectares will involve sustainably managed wood-based biomass approaches; and Burkina Faso, where 441,000 hectares are currently under sustainable forest management, and 270,000 are to be added. Ethiopia plans to bring 300,000 hectares of natural forest under participatory management schemes. In Madagascar, much of the charcoal consumed in the capital Antananarivo comes from sustainable eucalyptus plantations established around the capital since colonial times (World Bank 2011b). The last few years have also seen the launch of large-scale CBFM projects in Tanzania as part of the REDD+ initiative. 174 See note 142 and related text. The report team believes that despite numerous challenges, such as a lack of financing, the renewable biomass fuel sector is on the verge of much broader experimentation and scale-up, as charcoal prices in many countries have approached or begun to exceed the costs of briquette/pellet production, making this market attractive for entry. The growing dynamism of this market is obvious in the launch of Inyenyeri and other companies in at least eight African countries focused on developing mid- to large-scale briquette fuel supply for households (targeting urban charcoal consumers in particular). 175 See the GLPGP/Global Alliance for Clean Cookstoves recent report on the Kenya LPG market (Dalberg 2013); general information on the Global LPG Partnership is available at www.GLPGP.com. 176 Manufacturing labor costs in key stove-manufacturing markets in Africa (e.g., Kenya), China, and India have risen 8–13%; steel prices, accounting for 70–90% of stove-material costs depending on product, have been highly volatile, vacillating from US$500 to US$1,100 per MT (U.S. hot-rolled-coil steel) in the past five years. LPG and electric stoves are, of course, very different technologically from industrial ICS, but are likewise not expected to come down significantly in cost since (1) these technologies are already manufactured at great scale globally, including lower-cost models available in the SSA market; and (2) some of the same labor and materials cost concerns apply. 177 See Kojima et al. (2011). The most notable successful example of small-cylinder promotion is that of Indonesia, where the government subsidized the distribution of 3-kg cylinders and cookstoves as part of its kerosene elimination campaign. 178 See www.projectgaia.com. 179 Project Gaia, for instance, has worked on producing and commercializing methanol captured from flared gas in Nigeria in large-scale methanol stove pilots (see http://www.projectgaia.com/page.php?page=nigeria); the Protos BSH Bosh and Siemens jatropha oil stoves have been discontinued by the manufacturer, but entrepreneurs are continuing to promote an artisanally manufactured jatropha stove, the Jiko Safi, in Tanzania. See, for instance, Oketch (2013), showing that significant improvements are possible for baseline ethanol stove models, 180 such as the Moto Safi. See, generally, the overview of ethanol cooking appliances in Puzzolo (2013). SimGas markets both urban digester models (e.g., the GesiSafi, which uses kitchen waste) and larger-scale rural digester 181 models targeted at smallholder farmers (e.g., the GesiShamba, which uses animal manure). See www.simgas.com for details. 182 See www.ecofys.com/en/project/ecofys-plastic-bag-digester. 183 See www.biogaspro.com. 184 See the latest information on the new ACE stove design, drawing on patented Philips technology, at http://www. africancleanenergy.com/the-solution/. In BioLite’s case, stove-use monitoring data are logged by the stove-use monitor, and are then recorded onto an embedded 185 microSD card, which is electronically tagged to the specific stove, and can be collected by an untrained field worker. 186 For an overview of new PATS technologies, see Pillarisetti et al. (2014). BioLite holds significant IP globally and in Africa on the core heat-to-electricity TEG technology within cookstoves (see 187 patents EP2342500A1, WO2010042574A1, US20130112187, US8297271). 188 For pilots integrating TEG units into existing Africa ICS technologies, see O’Shaughnessy et al. (2014). 190 Biomass is exchanged at the rate of 5 kg of wood branches for 1 kg of fuel pellets, which the company reports is more than sufficient to meet most rural household cooking requirements. Households report that this system reduces the amount of fuelwood collected, and the time required to collect it, by about half from before signing the contract. The company 166 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report reported that rural household adoption rates are in the 70–99% range in the pilot area, and that retention rates are likewise high. 191 It is important to note that a number of the bigger Africa cooking-sector stakeholders—such as the Global Alliance, the World Bank, USAID, and GiZ—simultaneously play multiple roles across the landscape as coordination bodies, donors, research and learning providers, implementers (through local partners), and social impact investors. 192 USAID research on Africa cookstoves is channeled through several different programs, including WashPlus and Translating Research into Action (TRAction). 193 Major public health institutions with ongoing cookstove RCTs in Africa include the University of Liverpool, Columbia University Mailman School of Public Health, and the University of North Carolina at Chapel Hill. 194 See update on ISO/IWA process status in GACC (2014) and the Alliance’s Web site (http://cleancookstoves.org/). 195 SUMs have been adopted in many quality cookstove program and project evaluations in the past 2–3 years; see, e.g., Ruiz- Mercado et al. (2011) and Bensch et al. (2013). 196 See, e.g., the Biomass Energy Strategy for Rwanda (2009); a new biomass policy in progress in Tanzania in 2013–14; and new biomass and charcoal policies in Kenya 2012–13. 197 One example is the recent zero rating of stove importation tariffs in Rwanda. Discussions are in progress for similar steps in other geographies, but aside from ad hoc exceptions, in most cases, tariffs and taxes on imported stoves and stove components are a major obstacle. 198 See GACC (2012) for details on the volume of SSA cooking-sector research. 199 Gifford (2011). 200 See Muchiri (2008) for Kenya, Habermehl (2007) for Malawi, and Bensch and Peters (2011) for Senegal. 201 Kojima et al. (2011). 202 Schwebel et al. (2009). 203 GACC (2013). 204 See http://cdm.unfccc.int/ProgrammeOfActivities/registered.html (accessed February 25, 2014). 205 See the Gold Standard VER registry at http://mer.markit.com/br-reg/public/index.jsp (accessed March 1, 2014). The “Gold Standard” is a standard used when creating emission reduction projects in the Clean Development Mechanism (CDM) Joint Implementation (JI) and Voluntary Carbon Market. As of early 2014, in alphabetical order, African countries with CDM-registered cookstove projects included Burkina Faso, 206 Burundi, Cameroon, Côte d’Ivoire, Ethiopia, Ghana, Kenya, Malawi, Mali, Nigeria, Rwanda, Senegal, South Africa, Togo, Uganda, and Zambia. Registered and listed Gold Standard VER stoves projects are additionally present in Niger, Guinea, and Lesotho. 207 See, e.g., https://www.gov.uk/result-based-financing-for-low-carbon-energy-access-rbf. 208 IMC Worldwide (2014). See http://www.cquestcapital.com/wp-content/uploads/2013/05/Health_reductions_paper_4_19_2013.pdf and http:// 209 www.worldbank.org/content/dam/Worldbank/document/HDN/Health/021214CQCandLaosStovesNewcombe.pdf. 210 See http://www.cardanodevelopment.com/initiatives/bix-fund-management-company. 211 In 2010, IEA estimated total global spending of US$70 million annually on improved biomass stoves and up to US$1 billion annually on clean and improved cooking, once LPG, biogas, and other renewable and modern fuels were included. The proportion of these investments focused on Africa is unclear. Dalberg (2013) has separately assessed SSA investments into clean and improved cooking at US$100–200 million annually for SSA, using bottom-up reported program data from donors, such as GIZ, DFID, WB/IFC, and USAID; CDM data; and publicly available data on private-sector investments, including the latest data on carbon finance streams. i See the latest information on the new ACE stove design, drawing on patented Philips technology, at http://www. africancleanenergy.com/the-solution/. In BioLite’s case, stove-use monitoring data are logged by the monitor and then recorded onto an embedded microSD ii card, which is electronically tagged to the specific stove, and can be collected by an untrained field worker. iii For an overview of new PATS technologies, see Pillarisetti et al. (2014). 167 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Bibliography Abd’razack, Nelson T. A., and Ahmad Nazir bin M. L. 2012. “Benchmarking Sustainability and Ecological Footprint of African Cities.” Proceedings of SEATUC Conference in Bangkok, Thailand, March 2012. Adkins, E., et al. 2010. “Field Testing and Survey Evaluation of Household Biomass Cookstoves in Rural Sub- Saharan Africa.” Energy for Sustainable Development 14: 172–85. AED (Academy for Educational Development). December 2008. Fuel Efficient Stove Programs in IDP Settings – Summary Evaluation Report. Kampala, Uganda: USAID. Apsleya, A., et al. March 2014. “Switching to biogas – What effect could it have on indoor air quality and human health?” Biomass and Bioenergy, DOI: 10.1016/j.biombioe.2014.01.054. Bacon, R., S. Bhattacharya, and M. Kojima. 2010. Expenditure of Low-Income Households on Energy: Evidence from Africa and Asia. Washington, DC: World Bank. Banerjee, M., S. Siddique, A. Dutta, and B. Mukherjee. 2012. “Cooking with Biomass Increases the Risk of Depression in Pre-Menopausal Women. “ Social Science & Medicine 75(3): 565–72. Banerjee, A., and S. Mullainathan. 2010. “The Shape of Temptation: Implications for the Economic Lives of the Poor.” Cambridge: Harvard University, BREAD, NBER. Barnes, D.F., K. Openshaw, K. R. Smith, et al. 1994. “What makes people cook with improved biomass stoves? A comparative international review of stove programs.” World Bank Technical Paper: Energy Series 242. Washington, D.C.: World Bank. Barstow, C.K., F. Ngabo, G. Rosa, F. Majorin, and S. Boisson. 2014. Designing and Piloting a Program to Provide Water Filters and Improved Cookstoves in Rwanda. PLoS ONE 9 (3): e92403. Beltramo, T., D. Levine, and G. Blalock. 2014a. “The Effect of Marketing Messages, Liquidity Constraints, and Household Bargaining on Willingness to Pay for a Nontraditional Cook-stove.” CEGA Working Paper Series. Berkeley: University of California. Beltramo, T., G. Blalock, D. Levine, and A. Simons. 2014b. “Does Peer Use Influence Adoption of Efficient Cookstoves? Evidence from a Randomized Controlled Trial in Uganda.” CEGA Working Paper Series. Berkeley: University of California. Bensch, G., and J. Peters. 2011. Impacts of Improved Cooking Stove Dissemination: Evidence from Urban Senegal. Essen: RWI. Bensch, G., M. Grimm, K. Peter, et al. 2013. Impact Evaluation of Improved Stove Use in Burkina Faso – FAFASO. Essen, Germany: Rheinisch-Westfalisches Institut fur Wirtschaftsforschung. Berkeley Air Monitoring Group. 2010. Evaluation of Manufactured Wood-Burning Stoves in Dadaab Refugee Camps. Washington, DC: USAID. ———. 2012. Stove Performance Inventory Report. Washington, DC: Global Alliance for Clean Cookstoves. Bhargava, A., R. N. Khanna, S.K. Bhargava, and S. Kumar. 2004. “Exposure Risk to Carcinogenic PAHs in Indoor Air During Biomass Combustion Whilst Cooking in Rural India.” Atmospheric Environment 38 (28): 4761–7. Blackden, M. and Q. Wodon. 2006. Gender, Time Use, and Poverty in Sub-Saharan Africa. Washington, DC: World Bank. Bond, T. C., et al. 2013. “Bounding the role of black carbon in the climate system: A scientific assessment.” Journal of Geophysical Research 118: 5380–5552, doi:10.1002/jgrd.50171. Bonjour, S., H. Adair-Rohani, J. Wolf, et al. 2013. “Solid fuel use for household cooking: country and regional estimates for 1980–2010.” Environmental Health Perspectives 121: 784–90. Bryan, G., S. Chowdhury, and A. M. Mobarak. 2014. “Under-Investment in a Profitable Technology: The Case of Seasonal Migration in Bangladesh.” Econometrica (forthcoming). 168 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Bruce N., Perez-Padilla, R., and Albalak, R.. 2000. Indoor air pollution in developing countries: a major environmental and public health challenge. Bulletin of the World Health Organization, 78: 50. Bruce, N., Dheran, M., Liu, R., Hosgood, H.D., Sapkota, A., Smith, K.R., Straif, R., Lan, Q., Pope, D.., Does household use of biomass fuel cause lung cancer? A systematic review and evaluation of the evidence for the GBD 2010 study, Thorax, doi:10.1136/thoraxjnl-2014-206625 Burnett, T. R., et al. 2014. “An Integrated Risk Function for Estimating the Global Burden of Disease Attributable to Ambient Fine Particulate Matter Exposure.” Environ. Health Perspectives, DOI:10.1289/ehp.1307049 Burwen, J. 2011. From Technology to Impact: Understanding and Measuring Behavior Change with Improved Biomass Stoves. Berkeley: University of California. Burwen, J., and D. I. Levine. 2012. “A Rapid Assessment Randomized-Controlled Trial of Improved Cookstoves in Rural Ghana.” Energy for Sustainable Development 16 (3): 328–338. Cecelski, E., 2004. Re-thinking gender and energy: Old and new directions, ENERGIA/EASE Discussion Paper. ETC, The Netherlands. Cecelski, E., 2000. The role of women in sustainable energy development, National Renewable Energy Laboratory, NREL/SR-550-26889 Available at http://www.nrel.gov/docs/fy00osti/26889.pdf Chabossou, A., C. Stork, M. Stork, and Z. Zahonogo. April 17, 2009. “Mobile telephony access and usage in Africa.” 3rd Annual Conference on Information and Communication Technologies and Development: 2009 Proceedings. Education City, Doha, Qatar: Carnegie Mellon University in Qatar. Chazovachii, B., Chitongo, L., and Ndava, J. 2013. Reducing Urban Poverty through Fuel Wood Business in Masvingo City, Zimbabwe: A Myth or Reality, Bangladesh e-Journal of Sociology (10:1): 59. Chidamba, C. T. 2010. Report on the Impact Assessment of the POCA (POupa CArvão) Charcoal Stove in Mozambique. Johannesburg: ProBEC. Clancy, J. S., et al. 2011. “Gender Equity in Access to and Benefits from Modern Energy and Improved Energy Technologies.” Nor/Soer-konsulenterne. Clough, L. September 2012. The Improved Cookstove Sector in East Africa: Experience from the Developing Energy Enterprise Programme (DEEP). London: Global Villages Energy Partnership (GVEP) International. Concern Universal. 2012. “Socio-cultural acceptability of Improved Cook Stoves in Balaka, Dedza and Mulanje 2012.” Blantyre, Malawi: Concern Universal. Available at http://www.concern-universal.org/details_capture_ form/improved_cookstoves_final_full_report_pdf_1.pdf. Dalberg Global Development Advisors. 2013. “GLPGP [Global LPG Partnership]– Kenya Market Assessment.” Final Report. Washington, DC: GACC. Final Report. Available at http://www.cleancookstoves.org/resources_files/ glpgp-kenya-market-assessment.pdf. Daurella, D. C., and V. Foster. 2009. What Can Be Learned from Household Surveys on Inequality in Cooking Fuels in Sub-Saharan Africa. Washington, DC: Word Bank. Data monitor statistical review for LPG. Statistical Review of Global LP Gas (multiple years), see datamonitor.com Desalu, Olufemi Olumuyiwa, Ololade Olusola Ojo, Ebenezer Kayode Ariyibi, Tolutope Fasanmi Kolawole, and Ayodele Idowu Ogunleye. 2012. “A community survey of the pattern and determinants of household sources of energy for cooking in rural and urban south western, Nigeria.” The Pan African Medical Journal 12 (2). Available at http://www.panafrican-med-journal.com/content/article/12/2/full Demographic and Health Surveys (DHS) Program, see www.DHSprogram.com Dherani, M., D. Pope, M. Mascarenhas, and K. Smith. 2008. “Indoor Air Pollution from Unprocessed Solid Fuel Use and Pneumonia Risk in Children Aged Under Five Years: A Systematic Review.” Bulletin of the World Health Organization 86 (5): 390–398. Dooho, C., J. R. Guernsey, K. Critchley, and J. VanLeeuwen. 2012. “Pilot Study on the Impact of Biogas as a Fuel Source on Respiratory Health of Women on Rural Kenyan Smallholder Dairy Farms.” Journal of Environmental and Public Health vol. 2012, Article ID 636298, 9 pages, doi:10.1155/2012/636298. 169 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Dutch Ministry of Foreign Affairs. 2013. Impact Evaluation of Improved Cooking Stoves in Burkina Faso. The Hague Edelstein, M., E. Pitchforth, G. Asres, et al. December 2013. “Awareness of health effects of cooking smoke among women in the Gondar Region of Ethiopia: a pilot survey.” BMC International Health and Human Rights 8:10. EEP (Energy and Environment Partnership). January 2012. Analysing briquette markets in Tanzania, Kenya, and Uganda. Gauteng, South Africa: EEP. Ekouevi, K. and V. Tountivate. 2012. Households Energy Lessons for Cooking and Heating: Lessons Learned and the Way Forward. Washington, DC: World Bank. EPA (Environmental Protection Agency). 2011. Black Carbon Report to Congress. Washington, DC: EPA. EPHS - Eritrea Population and Health Survey (EPHS), 2010, Government of Eritrea, available at www.malariasurveys. org Evodius, R. 2010. Household Stoves Impact Assessment Report (Tanzania). South Africa: GIZ/ProBEC. Ezzati, M. & Kammen, D. M., 2002. “The health impacts of exposure to indoor air pollution from solid fuels in developing countries: Knowledge, gaps, and data needs. Environmental Health Perspectives, 110(11), pp. 1057–1068. Ferguson, H. 2012. Briquette Businesses in Uganda: The Potential for Briquette Enteprise to Address the Sustainability of the Ugandan Biomass Fuel Market. London: GVEP. Franco Suglia, S. et al., 2008. Association of Black Carbon with Cognition among Children in a Prospective. American Journal of Epidemiology, 167(3), pp. 280–286. Fullerton, D. G., N. Bruce, and S. Gordon. B. 2008. I. “Indoor Air Pollution from Biomass Fuel Smoke Is a Major Health Concern in the Developing World.” Transactions of the Royal Society of Tropical Medicine and Hygiene 102 (9): 843–851. GACC - Global Alliance for Clean Cookstoves. 2012. Igniting Change: A Strategy for Universal Adoption of Clean Cookstoves and Fuels. Washington, DC: United Nations Foundation. ______ , 2013. Global Alliance for Clean Cookstoves Rwanda Market Assessment: Sector Mapping. Accenture Development Partnerships. Available at ______ , 2013. Results Report 2012: Sharing progress on path to adoption of clean cooking solutions. United Nations Foundation. Available at http://www.cleancookstoves.org/resources_files/results-report-2012.pdf. ______ , 2014. Results Report 2013: Sharing progress on path the adoption of clean cooking solutions. United Nations Foundation. Garcia Frapolli, E., A. Schilmann, and V. Berrueta. 2010. “Beyond Fuelwood Savings: Valuing the Economic Benefits of Introducing Improved Biomass Cookstoves in the Purepecha Region of Mexico.” Ecological Economics 69 (12): 2598–2605. Gebreegziabher, Z., A. Damte, A. Mekonnen, et al. February 7, 2014. Can Improved Biomass Cookstoves Contribute to REDD+ Contracts in Low-Income Countries? Initial Results from a Randomized Trial in Ethiopia. Presented at the World Bank 2014 Land and Poverty Conference. Giffords, M. L. “A Global Review of Cookstove Programs.” Thesis. Berkeley: UC Berkeley. Available at http://www. eecs.berkeley.edu/~sburden/misc/mlgifford_ms_thesis.pdf. Global Burden of Disease database, Institute of Health Metrics, www.healthdata.org/gbd. Global LPG Partnership/Global Alliance for Clean Cooktoves (GLPGP/GACC), Kenya LPG Market Assessment, 2013. Available at https://cleancookstoves.org/binary-data/RESOURCE/file/000/000/234-1.pdf Grieshop, A. P., J. D. Marshall, M. Kandlikar. 2011. “Health and climate benefits of cookstove replacement options.” Energy Policy 39: 7530–42. Habermehl, H. 2007. Economic Evaluation of the Improved Household Cooking Stove Dissemination Programme in Uganda. Deutsche Gesellschaft fur Technische Zusammenarbeit (German Agency for Technical Cooperation; GTZ). 170 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Hamlin, A. 2012. Assessment of Social and Economic Impacts of Biogas Digesters in Rural Kenya. Independent study project, SIT Graduate Institute. Hammond, A. L., et al. 2007. The Next 4 Billion: Market Size and Business Strategy at the Base of the Pyramid. Washington, DC: World Resources Institute and International Finance Corporation. Hanna, R., E. Duflo, and M. Greenstone. 2012. Up in Smoke: The Influence of Household Behavior on the Long-Run Impact of Improved Cooking Stoves. Cambridge, Mass.: MIT Department of Economics. Harrell, S., C. Toombs, and J. Young. December 2013. A Guide to Optimizing Behavior Change in Fuel Efficient Stove Programs, USAID. Available at http://tractionproject.org/sites/default/files/A%20Guide%20to%20 Optimizing%20Behavior%20Change%20in%20Fuel%20Efficient%20Stove%20Programs_Final.pdf. Hawley, B., and J. Vockens. February 2013. “Pro-Inflammatory Effects of Cook Stove Emissions on Human Bronchial Epithelial Cells,” Indoor Air 23(1): 4-13. Hiemstra-van der Horst, G., and A. J. Hovorka. 2008. “Reassessing the ‘Energy Ladder’.” Energy Policy 36: 3333–44. Honkalaskar, V. H., U. V. Bhandarkar, and M. Sohoni. 2013. “Development of a fuel efficient cookstove through a participatory bottom-up approach.” Energy, Sustainability, and Society 3: 16, available at doi: 10.1186/2192- 0567-3-16. Hosgood, H. Dean, et al. “The potential role of lung microbiota in lung cancer attributed to household coal burning exposures.” Environmental and molecular mutagenesis 55.8 (2014): 643-651. Huba, E-M., and Paul, E., 2007, National Domestic Biogas Program Rwanda: Baseline study report, SNV, The Hague, Netherlands. Available at http://www.snvworld.org/en/publications/baseline-study-national-domestic- biogas-programme Hutton, G., E. Rehfuess, and F. Tediosi. December 2007. “Evaluation of the Costs and Benefits of Interventions to Reduce Indoor Air Pollution.” Energy for Sustainable Development 11 (4): 34–43. iDE, 2011, Biogas user survey, Bangladesh 2010, SNV The Hague, Netherlands. Available at http://www.snvworld. org/en/publications/biogas-user-survey-bangladesh-2010 IDEO.org. 2012. Cookstoves in Tanzania: User Insights and Opportunities. Washington, DC: Global Alliance For Clean Cookstoves. IEA (International Energy Agency). 2010. Energy Poverty: How to Make Modern Energy Access Universal? Paris: OECD/IEA. IFC (International Finance Corporation). 2012. From Gap to Opportunity: Business models for scaling up energy access. Washington D.C.: IFC. IFC/Lighting Africa. 2010. Solar Lighting at the Base of the Pyramid. Washington D.C. IFC IMC Worldwide. April 2014. Results-Based Financing for Clean Cookstoves in Uganda. Africa Clean Cooking Energy Solutions (ACCES) Program. Washington D.C.: World Bank Group. Jacobson, M. Z. (2010), Short term effects of controlling fossil‐fuel soot, biofuel soot and gases, and methane on climate, Arctic ice, and air pollution health, J. Geophys. Res., 115, D14209, doi:10.1029/2009JD013795. Jetter, J., Y. Zhao, K. R. Smith, et al. 2012. “Pollutant Emissions and Energy Efficiency under Controlled Conditions for Household Biomass Cookstoves and Implications for Metrics Useful in Setting International Test Standards.” Environmental Science and Technology 46 (19): 10827–34, doi: 10.1021/es301693f. Jeuland, M. and S. K. Pattanayak. 2012. “Benefits and Costs of Improved Cookstoves: Assessing the Implications of Variability in Health, Forest and Climate Impacts.” PLOS ONE, 7 (2): e30338. JRI Research. 2011. Biogas User Survey: Indonesia. The Hague: Hivos. Kar, A. et al. 2011. “Real-Time Assessment of Black Carbon Pollution in Indian Households due to Traditional and Improved Biomass Cookstoves.” Atmospheric Chemistry and Physics Discussions 11: 10845–74. Karekezi, S., Kimani, J., and Onguru, O., 2008. Energy access among the Urban and PeriUrban Poor in Kenya. AFREPREN/FWD, Nairobi, Kenya. 171 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Khonje, T. 2010. Impact Assessment of Portable Clay Stoves (Malawi). Johannesburg: ProBEC. Kiros, B. G. 2011. Environmental Resources Collection Versus Children’s Schooling: Evidence from Tigray, Northern Ethiopia. Addis Ababa: Addis Ababa University. Kohlin, G., E. O. Sills, S. K. Pattanayak, and C. Wilfong. 2011. Energy, Gender and Development: What Are the Linkages? Where is the Evidence? Washington, DC: World Bank. Kojima, M., R. Bacon, and X. Zhou. 2011. Who Uses Bottled Gas? Evidence from Households in Developing Countries. Washington, D.C.: World Bank. Kurmi, O., S. Semple, P. Simkhada, and W. Smith. 2010. “COPD and Chronic Bronchitis Risk of Indoor Air Pollution from Solid Fuel: A Systematic Review and Meta-Analysis.” Thorax 65: 221–8. Lam, N. L., K. R. Smith, A. Gauthier, and M. N. Bates. 2012. “Kerosene: A Review of Household Uses and their Hazards in Low and Middle Income Countries.” Journal of Toxicology and Environmental Health 15(6): 396–432. Lawson, D. 2007. Gender and Poverty: Empirical Methods and Evidence. In Gender and Economics. Ghana, World Bank. eScholarID:88740 Lee, C., C. Chandler, M. Lazarus, and F. X. Johnson. Assessing the Climate Impacts of Cookstove Projects: Issues in Emissions Accounting. Working Paper 2013-01. Stockholm: Stockholm Environment Institute. Levine, D. I., and T. Beltramo. 2012. The Effect of Solar Ovens on Fuel Use, Emissions, and Health: Results from a Randomized Controlled Trial. Berkeley: University of California. Levine, D. I.; T. Beltramo, G. Blalock, and C. Cotterman. 2012. What Impedes Efficient Adoption of Products? Evidence from Randomized Variation in Sales Offers for Improved Cookstoves in Uganda. UC Berkeley: Center for Effective Global Action. Lewis, J. J., and S.K. Pattanayak. 2012. “Who Adopts Improved Fuels and Cookstoves? A Systematic Review” Environmental Health Perspectives 120, 5: 637–635 Lighting Africa. Lighting Africa Market Trends Report 2013: Overview of the Off-Grid Lighting Market in Africa. http:// lightingafrica.org. Lim S. S., T. Vos, A. D. Flaxman, et al. 2012. “A comparative risk assessment of burden of disease and injury attributable to 67 risk factors and risk factor clusters in 21 regions, 1990–2010: a systematic analysis for the Global Burden of Disease Study 2010.” The Lancet 380 (9859): 2224-60, available at doi: 10.1016/S0140- 6736(12)61766-8. MacCarty, N., et al. 2008. “A Laboratory Comparison of the Global Warming Impact of Five Major Types of Biomass Cooking Stoves.” Energy for Sustainable Development 12 (2): 5–14. Malla, M. B., N. Bruce, E. Elizabeth Bates, and E. Rehfuess. 2011. “Applying Global Cost-Benefit Analysis Methods to Indoor Air Pollution Mitigation Interventions in Nepal, Kenya and Sudan: Insights and Challenges.” Energy Policy 39 (12): 7518–29. Malla, S., and G. R. Timilsina. June 2014. Household Cooking Fuel Choice and Adoption of Improved Cookstoves in Developing Countries. World Bank Policy Research Working Paper #6903. Washington, D.C.: World Bank. Manyo-Plange, N. C. 2011. The changing climate of household energy: Determinants of cooking fuel choice in domestic settings in Axim, Ghana. Available at http://www.cleancookstoves.org/resources_files/the- changing-climate-of.pdf. Malinski, B. 2006. Impact Monitoring Study: The Rocket Lorena Stove Dissemination in Bushenyi District.” Written on behalf of the Uganda Ministry of Energy and Mineral Development under the Energy Advisory Project supported by GTZ. University of Oldenburg. Martin, S. L., J. K. Arney, and L. M. Mueller, et al. 2013. “Using Formative Research to Design a Behavior Change Strategy to Increase the Use of Improved Cookstoves in Peri-Urban Kampala, Uganda.” International Journal of Environmental Research and Public Health 10: 6920–38, doi:10.3390/ijerph10126920. Masera, O., B. Saatkamp, and D. Kammen. 2000. “From linear fuel switching to multiple cooking strategies: a critique and alternative to the energy ladder model.” World Development 28 (12). Available at http://ssrn. com/abstract=252825. 172 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Megen Power Ltd. 2008. Impact Assessment of Mirt Improved Biomass Injera Stoves Commercialization in Tigray,Amhara, and Oromyia National Regional States. GTZ/SUN Energy Programme. Megen Power/GIZ. 2011. Final Report: Household Energy Baseline Survey in SNNPR. GIZ. Available at https:// energypedia.info/images/3/3b/Household_Bio-Energy_Baseline_Survey_in_SNNP_Region-Ethiopia.pdf. Mekonnen, A., and G. Kohlin. 2008. Determinants of household fuel choice in major cities in Ethiopia. Working Papers in Economics. Gothenburg: University of Gothenburg. Miller, B., and A. M. Mobarak. 2011. “Intra-Household Externalities and Low Demand for a New Technology: Experimental Evidence on Improved Cookstoves.” Stanford University. Miller, G., and A. M. Mobarak. 2013. Gender Differences in Preferences, Intra-Household Externalities, and Low Demand for Improved Cookstoves, NBER Working Paper No. 18964. Mishra, V., and R. Retherford. 2007. “Does Biofuel Smoke Contribute to Anaemia and Stunting in Early Childhood?” International Journal of Epidemiology 36 (1): 117–29. Misra, P., R. Srivastava, and A. Krishnan. 2012. “Indoor Air Pollution-Related Acute Lower Respiratory Infections and Low Birthweight: A Systematic Review.” Journal of Tropical Pediatry 58 (6): 457–466. Mobarak, A. M., P. Dwivedi, R. Bailis, L. Hildemann, L., and G. Miller. 2012. “Low demand for nontraditional cookstove technologies.” Protocols of the National Academy of Science 109: 10815–20. Mobarak, M. and M. Grant. 2013. Gender Differences in Preferences, Intra-Household Externalities, and the Low Demand for Improved Cookstoves. Poverty Action Lab. Mohlakoana, N., and W. Annecke. June 2008. Finally Breaking the Barriers: South African case study on LPG use by low-income urban households. Cape Town, South Africa: Human Sciences Research Council. Muchiri L. 2008. Gender and Equity in Bioenergy Access and Delivery in Kenya. PISCES (Policy Innovation Systems for Clean Energy Security). Mullainathan, S., and E. Shafir. 2011. “Savings Policy and Decision Making in Low-Income Households.” In Insufficient Funds, Michael Barr and Rebecca Blank, eds. (New York: Russell Sage Foundation), 121–46. Nankhuni, F. J. and J. L. Findeis. 2004. “Natural resource-collection work and children’s schooling in Malawi.” Agricultural Economics 31 (2–3): 123–134. Nelson, P. 1970. Information and Consumer Behavior, Journal of Political Economy (78:2), 311-329. Ndiritu, S. and W. Nyangena. 2010. Environmental Goods Collection and Children’s Schooling: Evidence from Kenya. Stockholm, Sweden: Environment for Development. Nicholson, D., and K. Beevers. 2013. Market Analysis for Fuel Efficient Cook Stoves in the Acholi Sub-Region, Uganda. Nigeria Alliance for Clean Cookstoves (NACC), Project Document for National Clean Cookstoves Programme for Nigeria (2013) (unpublished) Njogu, P. and Kung’u, J. 2013. Factors Influencing Adoption of Woodfuel Energy Saving Technologies in Nakuru County, Kenya, International Journal of Science and Research (IJSR), ISSN (Online): 2319-7064 Mercy Corps. Available at http://www.mercycorps.org/research-resources/market-analysis-fuel-efficientcook- stoves-acholi-sub-region-uganda. Obueh, J. 2008. Results of Project Gaia’s CleanCook Methanol Stove Pilot Study in Delta State, Nigeria. Final Report. CEHEEN/Project Gaia Nigeria. Available at https://www.projectgaia.com/files/NigeriaFinalPilotStudyReport. pdf. O’Dell, K., O. Irish, S. J. Maxted, and S. Peters. 2013. Generating consumer demand for clean cookstoves in base-of- pyramid markets. Deloitte University Press. Oketch, P. 2013. “Optimization of performance of bio-ethanol gel cookstove.” MS Mechanical Engineering Dissertation. Jomo Kenyatta University of Agriculture and Technology. Oksanen, T., Pajari, B. & Tuomasjukka, T., 2003. Forests in Poverty Reduction Strategies: Capturing the Potential, s.l.: European Forestry Institute Proceedings. 173 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report O’Shaughnessy, S. M., et al. 2014. “Field trial testing of an electricity-producing portable biomass cooking stove in rural Malawi.” Energy for Sustainable Development 20: 1–10. O’Sullivan, K. and Barnes, D. 2006. Energy Policies and Multitopic Household Surveys, Energy and Mining Sector Board Discussion Paper No. 17, World Bank, Washington DC. Available at http://web.worldbank.org/archive/ website00002/WEB/PDF/ENERGYGU.PDF Peck, M.D., G. E. Kruger, W. van der Merwe, et al. 2008. “Burns and fires from flammable non-electric domestic appliances: Part 1. The Scope of the Problem.” Burns 34: 303–11. Person, B., J. D. Loo, M. Owuor, et al. 2012. “’It Is Good for My Family’s Health and Cooks Food in a Way That My Heart Loves’: Qualitative Findings and Implications for Scaling Up an Improved Cookstove Project in Rural Kenya.” International Journal of Environmental Research and Public Health 9: 1566–80, doi:10.3390/ ijerph9051566. Pennise D., Smith K., Kithinji J, Rezende M, Raad T, Zhang J. 2001. Emissions of greenhouse gases and other airborne pollutants from charcoal making in Kenya and Brazil. J Geophys Res-Atmos (106), 24143–55. Perera, F. P., Tang, D. & Wang, S., 2012. Prenatal Polycyclic Aromatic Hydrocarbon (PAH) Exposure and Child Behavior at Age 6–7 Years. Environ Health Perspect., 120(6), pp. 921–926. Pillarisetti A., Johnson M.A., Allen T., Garland C.R., Charron D.H., Pennise D. M., Smith K. R. Characterizing PATS+sensor responses to air pollutants and integrating stove usage data for household energy assessments. Indoor Air 2014, Session D1: Smart and mobile Technologies, Hong Kong: July 8, 2014. Pokhrel, A., Smith, K., Khalakdina, A. & Deuja, A., 2005. Case–control study of indoor cooking smoke exposure and cataract in Nepal and India. International Journal of Epidemiology, Volume 34, pp. 702–708. Pokhrel, A., Bates, M., Verma, S., Joshi, H., Sreeramareddy, C. & K. R. Smith. 2010. Tuberculosis and indoor biomass and kerosene use in Nepal: A case-control study, Environmental Health Perspectives (118), 558. Practical Action. 2011. Ethanol as a Household Fuel in Madagascar: Health Benefits, Economic Assessment and Review of African Lessons for Scaling Up. Washington, DC: World Bank. ———. May 2014. Baseline and feasibility assessment for alternative cooking fuels in Senegal. Washington, D.C.: World Bank Group. Programme for Basic Energy and Conservation (ProBEC), 2008, M&E Impact assessment report, GIZ (unpublished) Puzzolo, E., D. Stanistreet, D. Pope, N. Bruce, and E. Rehfuess. 2013. Factors influencing the largescale uptake by households of cleaner and more efficient household energy technologies. London: EPPI-Centre, Social Science Research Unit, Institute of Education, University of London. RBESS. 2009. Rwanda Biomass Energy Strategy, Mininfra, Kigali, Rwanda. Rehfuess, E.A., E. Puzzolo, D. Stanistreet, D. Pope, and N. G. Bruce. 2014. “Enablers and barriers to large-scale uptake of improved solid fuel stoves: a systematic review.” Environmental Health Perspectives 122:120–130; Available at http://dx.doi.org/10.1289/ehp.1306639. Reid, B., Ghazarian, A. & DeMarini, D., 2012. Research Opportunities for Cancer Associated with Indoor Air Pollution from Solid Fuel Combustion. Environ Health Perspect., 120(11), pp. 1495–98. Reynolds C.O, and Kandlikar M. 2008. Climate Impacts of Air Quality Policy: Switching to a Natural Gas-Fueled Public Transportation System in New Delhi. Environmental Science and Technology, Vol. 42, No. 16, pp. 5860-5865. Risseeuw, N. 2012. Household energy in Mozambique: A study on the socioeconomic and cultural determinants of stove and fuel transitions. Energy Research Center. Amsterdam: Vrije Universiteit Amsterdam. Roth, C. 2014. Micro-gasification: cooking with gas from dry biomass: 2nd edition. Eschborn, Germany: Gesellschaft fur Internationale Zusammenarbeit (GIZ). Available at http://www.drtlud.com/wp-content/ uploads/2014/04/giz2014-en-micro-gasification.pdf. Ruiz-Mercado, I., O. Masera, H. Zamora, and K. R. Smith. 2011. “Adoption and Sustained Use of Improved Cookstoves.” Energy Policy 39 (12): 7557–7566. 174 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Ruiz-Mercado, I., E. Canuz, and K. R. Smith. 2012. “Temperature dataloggers as stove use monitors (SUMs): Field methods and signal analysis.” Biomass and Bioenergy 47: 459–68. Schei, M. A., J. O. Hessen, K.R. Smith, and N. Bruce. 2004. “Childhood Asthma and Indoor Woodsmoke from Cooking in Guatemala.” Journal of Exposure Analysis and Environmental Epidemiology 14: 110–17. Schlag, N. and F. Zuzarte. 2008. Market Barriers to Clean Cooking Fuels in Sub-Saharan Africa: A Review of Literature. Stockholm: Stockholm Environment Institute. Schutze, E. 2010. Lesson Learned from ProBEC’s Impact Assessment Surveys. Johannesburg: ProBEC. Schwebel, David C., Dehran Swart, Siu-Kuen Azor Hui, Jennifer Simpson and Phumla Hobe., 2009. Paraffin- related injury in low-income South African communities: knowledge, practice and perceived risk. Bulletin of the World Health Organization, 87:700–706. Semple, S., Apsley, A., Wushishi, A. & Smith, J. 2014 , Commentary: Switching to biogas – what effect could it have on indoor air quality and human health?, Biomass & Bioenergy (70): 125-129, 10.1016/j.biombioe.2014.01.054. Sepp, 2008, cited in World Bank, 2011b; earlier estimates suggested 200,000 for charcoal production out of a total of over 500,000 (UNDP, 2012). Sharma, A. December 11, 2012. Appraisal of Improved Charcoal Cookstoves in Nairobi, Kenya with Burn Manufacturing. Boulder, Colorado: University of Colorado, Mortenson Center in Engineering for Developing Communities. Shell Foundation India. 2008–09. “Room to Breathe.” http://roomtobreathecampaigns.org/default.aspx, accessed 15 June 2012. ———. 2013. Social Marketing in India: Lessons Learned from efforts to foster demand for cleaner. Avail. at http:// www.shellfoundation.org/download/pdfs/FINAL+Social+Marketing+in+India.pdf. Siddiqui, A. R., K. Lee, and E. B. Gold. 2005. “Eye and respiratory symptoms among women exposed to wood smoke emitted from indoor cooking: a study from southern Pakistan.” Energy for Sustainable Development 9 (3): 58–66. Simon, G., Bailis, R., Baumgartner, J., Hyman, J., Laurent, A. 2014. Current debates and future research needs in the clean cookstove sector, Energy for Sustainable Development (20): 49–57. Smith, K., S. Mehta, and M. Maeusezahl-Feuz. 2004. “The Global Burden of Disease from Household Use of Solid Fuels: A Source of Indoor Air Pollution.” In Comparative Quantification of Health Risks: The Global Burden of Disease due to Selected Risk Factors. Geneva: World Health Organization. Smith, K. R., N. Bruce, and S. Mehta. 2010 (May 13). Presentation for the Global Burden of Disease Project, Risk Factor Review Meeting, Institute for Health Metrics and Evaluation. Seattle: University of Washington. Smith-Sivertsen, T., et al. 2009. “Effect of Reducing Indoor Air Pollution on Women’s Respiratory Symptoms and Lung Function: RESPIRE Guatemala Randomized Trial.” American Journal of Epidemiology 170 (2): 211–220. Sreeramareddy, C. T., R. R. Shidhaye, and N. Sathiakumar. 2011. “Association Between Biomass Fuel Use and Maternal Report of Child Size at Birth: An Analysis of 2005–06 India Demographic Health Survey Data.” BMC Public Health 11: 403. Sumpter, C. and D. Chandramohan. January 2013. “Systematic review and meta-analysis of the associations between indoor air pollution and tuberculosis.” Tropical Medicine International Health. 18 (1): 101–8, doi: 10.1111/tmi.12013. Synesis. 2011. Biogas user survey: Lao Biogas Pilot Project (BPP), SNV, available at http://www.snvworld.org/en/ countries/lao-pdr/publications/biogas-user-survey-lao-pdr-2011 Szulczewski, M. 2006. Lasting Impacts of Solar Cooker Projects. Washington, DC: Solar Household Energy, Inc. Takama, T., et al. 2011. Will African Consumers Buy Cleaner Fuels and Stoves? Stockholm: Stockhold Research Institute. Ternes, T., S. Bolton, and A. Donnelly. 2008. Estufa Finca: Santos Pilot Project Results Report. s.l.: SeaChar.org. 175 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report Thurber, M., Phadke, H., Nagavarapu, S., Shrimali, G., Zerriffi, H., 2014., ‘Oorja’ in India: Assessing a large-scale commercial distribution of advanced biomass stoves to households, Energy for Sustainable Development 19: 138–150. TNS. 2013. Uganda Clean Cooking Consumer Research, forthcoming, TNS/PAC. UNDP. 2000. World Energy Assessment: Energy and the Challenge of Sustainability. New York, United Nations Development Program. UNDP and WHO. 2009. The Energy Access Situation in Developing Countries, A Review Focusing on the Least Developed Countries and Sub-Saharan Africa, http://www.undp.org/energy UNFCC and Intergovernmental Panel on Climate Change (unpublished) UPDEA - Union of African Electricity Producers, Distributors, and Conveyors. 2009. “Comparative Study of Electricity Tariffs Used in Africa.” Available at http://www.updea-africa.org/updea/DocWord/TarifAng2010. pdf. USAID. 2009. Commercialization of improved cookstoves for reduced indoor air pollution in urban slums, Washington DC. Available at http://cleancookstoves.org/resources_files/commercialization-of-improved. pdf USAID and Winrock. 2011. The Kenyan household cookstove sector: current state and future oppotunities. Available at http://www.relwa.org/sites/default/files/Kenya-Stoves-Assessment-web.pdf USAID WashPlus Project. August 2013. Understanding Consumer Preference and Willingness to Pay for Improved Cookstoves in Bangladesh. Washington, D.C.: FHI Development 360. van der Kroon, B., R. Brouwer, and P. J. H. van Beukering. 2014. “The impact of the household decision environment on fuel choice behavior.” Energy Economics 44: 236–47. Venkataraman, C. et al., 2010. The Indian National Initiative for Advanced Biomass Cookstoves: The benefits of clean combustion. Energy for Sustainable Development, Volume 14, pp. 63–72. West, S. K., M. N. Bates, J. S. Lee, et al. November 2013. “Is Household Air Pollution a Risk Factor for Eye Disease?” International Journal of Environmental Research on Public Health 10 (11): 5378–98. Westinga, E., A. Mukashema, and H. van Gils. 2013. “A comparison of fine resolution census and image-based national forest inventories: a case study of Rwanda.” Forestry 86 (4): 453–61, doi:10.1093/forestry/cpt016. Weuve, J., R. C. Puett, J. Schwartz, et al. 2012. “Exposure to Particulate Air Pollution and Cognitive Decline in Older Women.” Archives of Internal Medicine 172 (3): 219, DOI:10.1001/archinternmed.2011.683 WHO (World Health Organization). Various years (1970–2010). Fuel Use Database. Available at http://www.who. int/indoorair/health_impacts/he_database/en. Winrock International. May 2009. Commercialization of Improved Cookstoves for Reduced Indoor Air Pollution in Urban Slums of Northwest Bangladesh. Washingon, D.C.: USAID. World Bank / Independent Evaluation Group (IEG). 2008. Gender and development (2002-2008): Evaluation Summary. Washington, DC: The World Bank Group World Bank. 2011a. Household Cookstoves, Environment, Health, and Climate Change: A New Look at an Old Problem. Washington, DC: The World Bank Group. ———. 2011b. Wood-Based Biomass Energy Development for Sub-Saharan Africa: Issues and Opportunities. Washington, DC: The World Bank Group. 176 Clean and Improved Cooking in Sub-Saharan Africa: A Landscape Report The World Bank 1818 H Street, N.W. Washington, D.C. 20433, U.S.A.