WORLD BANK TECHN1ICAL PAPER NO. 379 Work in progress .W TP3a9 for public discussion __________@e~. Iqq-^ Urban Air Quality Management Strategy in Asia Jak/U-111l Report AV Edited b '! Jilenra J. SAhp/ Ta1- i i z I agp a RECENT WORLD BANK TECHNICAL PAPERS No. 317 Schware and Kimberley, Information Technology and National Trade Facilitation: Guide to Best Practice No. 318 Taylor, Boukambou, Dahniya, Ouayogode, Ayling, Abdi Noor, and Toure, Strengthening National Agricul- tural Research Systems in the Humid and Sub-humid Zones of West and Central Africa: A Frameworkfor Action No. 320 Srivastava, Lambert, and Vietmeyer, Medicinal Plants: An Expanding Role in Development No. 321 Srivastava, Smith, and Forno, Biodiversity and Agriculture: Implicationsfor Conservation and Development No. 322 Peters, The Ecology and Management of Non-Timber Forest Resources No. 323 Pannier, editor, Corporate Governance of Public Enterprises in Transitional Economies No. 324 Cabraal, Cosgrove-Davies, and Schaeffer, Best Practicesfor Photovoltaic Household Electrification Programs No. 325 Bacon, Besant-Jones, and Heidarian, Estimating Construction Costs and Schedules: Experience with Power Generation Projects in Developing Countries No. 326 Colletta, Balachander, and Liang, The Condition of Young Children in Sub-Saharan Africa: The Convergence of Health, Nutrition, and Early Education No. 327 Vald6s and Schaeffer in collaboration with Martin, Surveillance of Agricultural Price and Trade Policies: A Handbookfor Paraguay No. 328 De Geyndt, Social Development and Absolute Poverty in Asia and Latin America No. 329 Mohan, editor, Bibliography of Publications: Technical Department, Africa Region, July 1987 to April 1996 No. 330 Echeverria, Trigo, and Byerlee, Institutional Change and Effective Financing of Agricultural Research in Latin America No. 331 Sharma, Damhaug, Gilgan-Hunt, Grey, Okaru, and Rothberg, African Water Resources: Challenges and Opportunities for Sustainable Development No. 332 Pohl, Djankov, and Anderson, Restructuring Large Industrial Firms in Central and Eastern Europe: An Empirical Analysis No. 333 Jha, Ranson, and Bobadilla, Measuring the Burden of Disease and the Cost-Effectiveness of Health Interventions: A Case Study in Guinea No. 334 Mosse and Sontheimer, Performance Monitoring Indicators Handbook No. 335 Kirmani and Le Moigne, Fostering Riparian Cooperation in International River Basins: The World Bank at Its Best in Development Diplomacy No. 336 Francis, with Akinwumi, Ngwu, Nkom, Odihi, Olomajeye, Okunmadewa, and Shehu, State, Community, and Local Development in Nigeria No. 337 Kerf and Smith, Privatizing Africa's Infrastructure: Promise and Change No. 338 Young, Measuring Economic Benefitsfor Water Investments and Policies No. 339 Andrews and Rashid, The Financing of Pension Systems in Central and Eastern Europe: An Overview of Major Trends and Their Determinants, 1990-1993 No. 340 Rutkowski, Changes in the Wage Structure during Economic Transition in Central and Eastern Europe No. 341 Goldstein, Preker, Adeyi, and Chellaraj, Trends in Health Status, Services, and Finance: The Transition in Central and Eastern Europe, Volume I No. 342 Webster and Fidler, editors, Le secteur informel et les institutions de microfinancement en Afrique de l'Ouest No. 343 Kottelat and Whitten, Freshwater Biodiversity in Asia, with Special Reference to Fish No. 344 Klugman and Schieber with Heleniak and Hon, A Survey of Health Reform in Central Asia No. 345 Industry and Mining Division, Industry and Energy Department, A Mining Strategy for Latin America and the Caribbean No. 346 Psacharopoulos and Nguyen, The Role of Government and the Private Sector in Fighting Poverty No. 347 Stock and de Veen, Expanding Labor-based Methods for Road Works in Africa No. 348 Goldstein, Preker, Adeyi, and Chellaraj, Trends in Health Status, Services, and Finance: The Transition in Central and Eastern Europe, Volume 11, Statistical Annex No. 349 Cummings, Dinar, and Olson, New Evaluation Proceduresfor a New Generation of Water-Related Projects No. 350 Buscaglia and Dakolias, Judicial Reform in Latin American Courts: The Experience in Argentina and Ecuador (List continues on the inside back cover) WORLD BANK TECHNICAL PAPER NO. 379 Urban Air Quality Management Strategy in Asia Jakarta Report SELECTED WORLD BANK TITLES ON AIR QUALITY Air Pollhtion from Motor Vehicles: Standards and Technologies for Controlling Emissions. Asif Faiz, Christopher S. Weaver, and Michael Walsh. Clean Futels for Asia: Technical Options for Moving towvard Unleaded Gasoline and Low-Suilfuir Diesel. Michael Walsh and Jitendra J. Shah. Technical paper no. 377. Energy Use, Air Polluttion, and Environmental Policy in Krakow: Can Economic Incentives Really Help? Seabron Adamnson, Robin Bates, Robert Laslett, and Alberto Ptotschnig. Technical paper no. 308. Taxing Bads by Taxing Goods: Pollution Control with Presumptive Charges. Gunnar S. Eskeland and Shantayanan Devarajan. Directions in Development Series. Urban Air Quiality Management Strategy in Asia: Kathmandu Valley Report. Edited by Jitendra J. Shah and Tanvi Nagpal. Technical paper no. 378. Urban Air Quality Management Strategy in Asia: Jakarta Report. Edited by Jitendra J. Shah and Tanvi Nagpal. Technical paper no. 379. Urban Air Quality Management Strategy in Asia: Metro Manila Report. Edited by Jitendra J. Shah and Tanvi Nagpal. Technical paper no. 380. Urban Air Quiality Management Strategy in Asia: Greater Muimbai Report. Edited by Jitendra J. Shah and Tanvi Nagpal. Technical paper no. 381. Urban Air Qiality Management Strategy in Asia: Guidebook. Edited by Jitendra J. Shah, Tanvi Nagpal, and Carter J. Brandon. Vehicuilar Air Polluition: Experiencesfrom Seven Latin American Urban Centers. Bekir Onursal and Surhid P. Gautam. Technical paper no. 373. AUTHORS Knut Erik Gr0nskei Frederick Gram Leif Otto Hagen Steinar Larssen Norwegian Institute for Air Research Kjeller, Norway Huib Jansen Xander Olsthoorn Institute of Environmental Studies at the Free University Amsterdam, the Netherlands Dr. Moestikahadi Soedomo Department of Environment Engineering Institute of Technology Bandung, Indonesia Dr. Umar F. Achmadi Faculty of Public Health, University of Indonesia iii WORLD BANK TECHNICAL PAPER NO. 379 Urban Air Quality Management Strategy in Asia Jakarta Report Edited by Jitendra J. Shah Tanvi Nagpal The World Bank Washington, D.C. Copyright © 1997 The International Bank for Reconstruction and Development/THE WORLD BANK 1818 H Street, N.W. Washington, D.C. 20433, U.S.A. All rights reserved Manufactured in the United States of America First printing December 1997 Technical Papers are published to communicate the results of the Bank's work to the development community with the least possible delay. The typescript of this paper therefore has not been prepared in accordance with the proce- dures appropriate to formal printed texts, and the World Bank accepts no responsibility for errors. Some sources cited in this paper may be informal documents that are not readily available. The findings, interpretations, and conclusions expressed in this paper are entirely those of the author(s) and should not be attributed in any manner to the World Bank, to 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 in- cluded in this publication and accepts no responsibility whatsoever for any consequence of their use. The boundaries, colors, denominations, and other information shown on any map in this volume do not imply on the part of the World Bank Group any judgment on the legal status of any territory or the endorsement or acceptance of such bound- aries. The material in this publication is copyrighted. Requests for permission to reproduce portions of it should be sent to the Office of the Publisher at the address shown in the copyright notice above. The World Bank encourages dissem- ination of its work and will normally give permission promptly and, when the reproduction is for noncommercial purposes, without asking a fee. Permission to copy portions for classroom use is granted through the Copyright Clearance Center, Inc., Suite 910, 222 Rosewood Drive, Danvers, Massachusetts 01923, U.S.A. Cover design by Beni Chibber-Rao. Cover photo of the National Monument used with permission of Bappeda DKI, Jakarta ISSN: 0253-7494 Jitendra J. Shah is an environmental engineer in the World Bank's Asia Technical Environment Unit. Tanvi Nagpal, a political economist, is a consultant in the World Bank's Asia Technical Environment Unit. Library of Congress Cataloging-in-Publication Data Urban air quality management strategy in Asia. Jakarta report / edited by Jitendra J. Shah, Tanvi Nagpal. p. cm. - (World Bank technical paper ; no. 379) Includes bibliographical references. ISBN 0-8213-4035-2 1. Air quality management-Indonesia-Jakarta Metropolitan Area. 2. Air-Pollution-Indonesia-Jakarta Metropolitan Area. 1. Shah, Jitendra J., 1952- . II. Nagpal, Tanvi, 1967- . III. Series. TD883.7.152J358 1997 363.739'25'0959822-dc2l 97-28976 CIP TABLE OF CONTENTS LETTER OF SUPPORTl..................................R - .-........... .-..........---..... x FOREWORD. xi ACKNOWLEDGMENTS ............................................................................................xii ABSTRACT ......................................................................................................... xiv ABBREVIATIONS AND ACRONYMS .................................. xv EXECUTIVE SUMMARY ....................................................................... 1 1. BACKGROUND INFORMATION ..................................5 SCOPE OF THE STUDY ....................................5 GENERAL DESCRIPTION OF JAKARTA ...................................5 DATA SOURCES ...................................6 Previous studies ................................. 6 URBAIR data collection ................................. 8 DEVELOPMENT OF JAKARTA, 1981-1992 ....................................8 POPULATION ...................................8 VEHICLE FLEET ................................... 10 INDUSTRIAL SOURCES ................................... 10 FUEL CONSUMPTION ................................... I 1 2. AIR QUALITY ASSESSMENT ................................... 13 AIR POLLUTION CONCENTRATIONS ................................... 13 Overview of database ................................. 13 Total suspended particles measurements ................................. 15 Nitrogen oxides measurements ..................................15 Ozone measurements ................................. 17 Carbon monoxide measurements ................................. 17 Lead measurements ................................. 18 AIR POLLUTANT EMISSIONS IN JAKARTA ................................... 18 Total emissions ................................. 18 TSP emission ................................. 22 NOx emission: ................................. 23 Lead emission ................................. 24 DISPERSION MODEL CALCULATIONS ................................... 25 Dispersion conditions ................................. 25 Dispersion model calculations .................................. 27 Pollution hot spots .................................. 29 vii POPULATION EXPOSURE TO AIR POLLUTION IN JAKARTA ................................................................... 29 Estimating population exposure in Jakarta ................................................................. 30 AIR QUALrIY ASSESSMENT SUMMARY ................................................................... 32 AIR QUALrFY ASSESSMENT ................................................................... 33 Data shortcomings ................................................................. 33 3. HEALTH IMPACTS OF AIR POLLUTION . ....................... 37 ASSESSING AND VALUING MORTALrrY AND MORBIDITY ................................................................... 37 MORBIDY .................................................................... 39 VALUATION OF HEALTH IMPACTS ................................................................... 40 CONCLUSIONS ................................................................... 41 4. ABATEMENT MEASURES: EFFECTIVENESS AND COSTS ......................................... 43 INTRODUCTION ................................................................... 43 TRAFFIC ....4.3 Introduction of low-lead or unleaded gasoline ................................................................. 44 Scheme for inspection and maintenance ................................................................. 45 Address excessively polluting vehicles ................................................................. 46 Improving diesel quality ................................................................. 46 Introduction of low-smoke lubricating oilfor two-stroke, mixed-lubrication engines ............... 47 Fuel switching in the transportation sector ................................................................. 48 Adoption of clean vehicle emissions standards ................................................................. 48 Improvements in abatement, and other propulsion techniques ................................................... 51 Addressing resuspension emissions ................................................................. 51 Improving traffic management ................................................................. 52 Constructing and improving mass-transit systems ................................................................. 52 CONTROLLING POLLUTION FROM LARGE POINT SOURCES ................................................................... 52 INDUSTRIAL PROCESSES (NON-COMBUSTION SOURCES) ................................................................... 53 OPEN BURNING AND CONSTRUCTION ................................................................... 53 CONCLUSIONS ................................................................... 53 5. ACTION PLAN ........................................................... 55 ACrIONS TO IMPROVE JAKARTA'S AIR QUALITY AND ITS MANAGEMENT . .............................................. 55 Actions to improve air quality ................................................................. 55 Actions to improve the AQMS ................................................................. 57 A COMPREHENSIVE LIST OF PROPOSED MEASURES AND ACTIONS ......................................................... 57 viii 6. INSTITUTIONS, FUNCTIONS, AND POLICY PLANS .............................................. 63 INSTITUTIONS ......................................................... 63 Central control ................................................ 63 Bureau of Environment ............................................... 63 Road Traffic and Transportation Department ............................................... 65 KPPL ............................................... 65 Environmental support network ............................................... 66 FUNCTIONS ................................................. 66 Monitoring ............................................... 69 Permits ............................................... 69 AMDAL environmental impact assessment ............................................... 69 Law enforcement ............................................... 69 Emissions standards ............................................... 69 EXISTING LAWS AND REGULATIONS ON AIR POLLUTION .............................................. 70 Recentpublications ............................................... 71 SHORTCOMINGS ........................................................ 72 R1FER~E~NCES ..............................................................................................................73..... APPENDICES 1: AIR QUALITY STATUS, JAKARTA .75 2: AIR QUALITY GUIDELINES .89 3: AIR POLLUTION LAWS AND REGULATIONS FOR INDONESIA AND DKI JAKARTA ...... 93 4: EMISSIONS SURVEY FOR JAKARTA ............................... ....................................... 103 5: EMISSION FACTORS, PARTICLES ...................................................................... 125 6: POPULATION EXPOSURE CALCULATIONS ...................................................................... 129 7: SPREADSHEETS FOR CALCULATING EFFECTS OF CONTROL MEASURES ON EMISSIONS .................................................................. 133 8: METEOROLOGY AND DISPERSION CONDITIONS IN JAKARTA ........................................ 137 9: PROJECT DESCRIPTON, LOCAL CONSULTANTS ............................................................... 145 ix ~~ffAw ¸~~47~~I2fffla7 IfAf Many urban areas in the world are on the threshold of a major environmental crisis in the form of air pollution. The deteriorating air quality in those areas is a result of rapid economic expansion, rise in population, increased industrial emissions and unprecedented growth of passenger vehicles. The impact of air pollution is well known: environmental deterioration, adverse health effects, rising health costs, damage to ecological and cultural properties. In Jakarta, the main contributor of air pollution is the transport sector, followed by statical emission sources like industrial units and power plants. In addition, there is air pollution emitted from incineration and solid waste disposal, construction industry, and consumption of CFC content products. Fuel quality and engine conditions significantly influence the level of air pollution. To arrest this growing problem, a concerted effort with public involvement is essential. Awareness of the issue, proactive policies, economically affordable standards and technologies and effective enforcement are key elements in an air quality management strategy. Early adoption of policies for environmentally safer technologies can allow developing countries to resolve some of the most difficult problems of industrialization and growth at lower human and economic cost. URBAIR has assisted the Provincial Government of Jakarta Capital City Region in developing a strategy and action plan for air quality management in Jakarta. It brought together the different stakeholders -- sectoral agencies, private sector, NGOs, academics, research bodies and media -- to formulate a strategy. This Technical Committee deliberated over several months with technical support provided by a team of national and international experts. The resulting action plan is truly impressive and Jakarta is fully committed to its implementation. We will need the support of the international community, as well as public participation, in realizing the goals of the action plan. I wish to acknowledge with gratitude all those who contributed to the development of the strategy and plan, especially MEIP for facilitating the process. Vice Governor for The Economic and Development Affair of Capital City Government b. M. Rais x FOREWORD In view of the potential environmental consequences of continuing growth of Asian metropolitan areas, the World Bank and United Nations Development Programme launched the Metropolitan Environmental Improvement Program (MEIP) in six Asian metropolitan areas: Beijing, Mumbai (Bombay), Colombo, Jakarta, Kathmandu Valley and Metro Manila. The mission of MEIP is to assist Asian urban areas address their environmental problems. Recognizing the growing severity of air pollution caused by industrial expansion and increasing numbers of vehicles, the World Bank through MEIP started the Urban Air Quality Management Strategy (URBAIR) in 1992. The first phase of URBAIR covered four cities: Mumbai (Bombay), Jakarta, Kathmandu, and Metro Manila. URBAIR is an international collaborative effort involving governments, academia, international organizations, NGOs, and the private sector. The main objective of URBAIR is to assist local institutions in developing action plans which would be an integral part of the air quality management system for the metropolitan regions. The approach used to achieve this objective involves the assessment of air quality and environmental damage (on health and materials), the assessment of control options, and comparison of costs of damage and costs of control options (cost-benefit or cost-effectiveness analysis). The preparation of this city-specific report for Jakarta is based upon the collection of data and specific studies carried out by the local consultants, and upon workshops and fact-finding missions carried out between 1993 and 1995. The Norwegian Institute for Air Research (NILU) and the Institute for Environmental Studies (IES) prepared first drafts of the report, before the first workshops. These were based on general and city-specific information available from earlier studies. Later draft reports were prepared before the second workshop, with substantial inputs from the local consultants, and assessment of air quality, damage and control options, and costs carried out by NILU and IES. The report concludes with an action plan for air pollution abatement produced by the local working groups as a result of the deliberations during the second workshop. NILU/IES carried out cost-benefit analysis of some selected abatement measures, showing the economic viability of many of the technical control options. It is hoped that this analysis will form the basis for further analysis of data, and formulation of strategies for air pollution control. Local institutions may refer to it as a preliminary strategy and use it in conjunction with the URBAIR Guidebook to formulate policy decisions and investment strategies. Maritta Koch-Weser Division Chief Asia Environment and Natural Resources Division xi ACKNOWLEDGMENTS We would like to acknowledge the groups and individuals who contributed to this report and the URBAIR program. Core funds for URBAIR were provided by United Nations Development Programme, the Royal Norwegian Ministry of Foreign Affairs, the Norwegian Consultant Trust Funds, and the Netherlands Consultant Trust Funds. Substantial inputs were provided by host governments and city administrations. The city-level technical working group provided operational support, while the steering committee members gave policy direction to the study team. The National Program Coordinator of MEIP-Jakarta, Mr. Suhadi Hadiwinoto, was key to the success of the program. In the World Bank's Environment and Natural Resources Division, Asia Technical Group, URBAIR was managed by Jitendra Shah, Katsunori Suzuki, and Patchamuthu Illangovan, under the advice and guidance of Maritta Koch-Weser, Division Chief, and David Williams, MEIP Project Manager. Colleagues from World Bank Country Departments and Jakarta Resident Mission offered program assistance and comments on the numerous drafts. Management support at the World Bank was provided by Sonia Kapoor, Ronald Waas, and Erika Yanick. Tanvi Nagpal and Sheldon Lippman were responsible for quality assurance, technical accuracy, and final production. Julia Lutz prepared the layout. Many international institutions including World Health Organization, Japan International Cooperation Agency (JICA), United States Environmental Protection Agency, and United States Asia Environment Partnership provided valuable contribution to the study through participation at URBAIR workshops and with follow-up correspondence and discussions throughout the study. xii Following are the individuals with affiliation who were participants in the Jakarta URBAIR working groups: Nabiel Makarim, MPA Deputy BAPEDAL, Agency for Environmental Impact Management Aca Sugandhi, MSc Assistant to the State Minister for Environment Tb. M. Rais Vice Govemor of Jakarta Didi Herkamto, MSc Director, Assessment of Service Industry, BPPT Prasetyo, MSc Director, Assessment of Human Settlement and the Environment, BPPT Prof. Dr. Umar Fahmi Director, Research Centre, University of Indonesia Prof. Retno Sutaryono, SH Director, Research Centre for Human Settlement and the Environment, University of Indonesia Dr. Sutramihardja State Ministry for Environment Dr. Mustikahadi Sudomo Head, Environmental Engineering Division, Bandung Institute of Technology Dr. Haryoto Faculty of Public Health, University of Indonesia Dr. Charles Suryadi Chairman of the Urban Health Study Group, Atmajaya University Dr. Saut Lubis Director for Marine and Air Pollution Control, BAPEDAL Ridwan Tamin, MSc Agency for Environmental Impact Management Budoyo, Msc Agency for the Assessment and Application of Technology Razak Manan, MBA Research & Development, Ministry of Transportation Ir. Abuyuwono Head of the Bureau of Environment, Jakarta Ir. K. Wirahadikusuma Bureau of Environment, Jakarta Ir. Ali Rozi Head, Urban and Environment Assessment Office, Jakarta Ir. Liliansari Urban and Environment Assessment Office, Jakarta Ir. Yunani Urban and Environment Assessment Office, Jakarta Ir. Rafjon Urban and Environment Assessment Office, Jakarta Ir. Suryadarma Urban and Environment Assessment Office, Jakarta Ir. Aurora Tambunan Regional Development Planning Board, Jakarta Ir. Rudy Tambunan, MSc City Planning Department, Jakarta Ir. Adlin Adel Traffic and Transportation Department, Jakarta Dr. Hardiwinoto Health Department, Jakarta Taty Herawati Department of Industry, Jakarta Dr. Tri Tugaswati Head of the Environmental Health Research Centre, Ministry of Health Ning Pumomohadi, MSc Trisakti University Barrid Manna CIDA, Canadian International Development Assistance xiii ABSTRACT Severe air pollution is threatening human health and the gains of economic growth in Asia's largest cities. This report aims to assist policy makers in the design and implementation of policies and monitoring and management tools to restore air quality in Jakarta, the booming capital of Indonesia. Tremendous growth in the human population, numbers of vehicles, and industrial development in the Jabotabek region have led to a significant deterioration in the air quality. Pollutant concentrations near the main roads, especially in the most industrial areas. Total suspended particle (TSP) emissions in Jakarta are estimated at 96,733 tons per year. PM1o (particulate matter of 10 microns or less) emissions total 41,369 tons per year, and nitrogen oxide (NOx) emissions are estimated at 43,031 tons per year. The annual TSP averages in the most polluted areas are 5 to 6 times the national air quality standard. High ozone concentrations, measured 30 to 40 kilometers outside Jakarta, indicate that secondary pollutants have developed as a result of NOx and VOC emissions in Jakarta. Using dose-response relationships developed in the United States, this report calculates that PM1o emissions caused a total of 4,364 excess deaths, 32 million restricted activity days, 101 million respiratory symptom days, innumerable emergency room visits, asthma attacks, cases of bronchitis in children, and hospital admissions, at a total cost of about US$300,000 (based on Indonesian data) in 1990. Applying the essential components of an air quality management system to the pollution problem in Jakarta, this report suggests an action plan that lists abatement measures for the short, medium and long terms. Recommended actions fall under two categories: institutional and technical. A single institution with a clear mandate and sufficient resources should be made responsible for air quality management in the city. In addition, data gathering and processing capabilities should be improved throughout the city. Technically, it is crucial that gross polluters be identified and penalized. Diesel quality should be improved and low-lead or unleaded gasoline be made cheaper than leaded to encourage its use. Clean vehicle emissions standards should be introduced for all vehicle classes. Inspection and maintenance of vehicles is necessary for the enforcement of such standards. The sulfur content of heavy fuel oil should also be reduced. Awareness raising through public and private organizations, including educational institutions, is key to bringing about policy change on matters related to air pollution. xiv ABBREVIATIONS AND ACRONYMS AADT annual average daily traffic IES Institute for Environmental AQG air quality guidelines Studies AQMS air quality management system KPPL Urban & Environmental BAPEDAL Environmental Impact Control Assessment Office Board LNG liquefied natural gas BKMPD Regional Investment Board LPG liquefied petroleum gas BLH Bureau of the Environment MTBE methyl-tertial-butyl-ether BMG Meteorological & Geophysical NILU Norwegian Institute for Air Agency Research CHD coronary heart disease NGO nongovernmental organization CNG compressed natural gas NOx nitrogen oxide CO carbon monoxide Pb lead DBP diastolic blood pressure PM1o particulate matter of 10 microns DKI KPPL District of Jakarta Research or less Centre for Urban Development ppb parts per billion DKK Department of Health RAD restricted activity days DLLAJR Road Traffic & Transportation RHD respiratory hospital diseases Department RON research octane number DPU Department of Public Works Rp Rupiahs EIA environmental impact RSD respiratory symptom days assessment SO2 sulfur dioxide ERV emergency room visits TSP total suspended particles g/l grams per liter ,ug/m3 particulate concentration, in GEMS Global Environment micrograms per cubic meters Monitoring System UNDP United Nations Development GNP gross national product Programme H2S hydrogen sulfide UNEP United Nations Environment HC hydrocarbon Programme Jabotabek Jakarta, Bogor, Tangerang, and USEPA United States Environment Bekasi Protection Agency JMG Jakarta Municipal Government VOC volatile organic compounds JUDP III Third Jakarta Municipal WHO World Health Organization Development Project WTP willingness to pay xv EXECUTIVE SUMMARY URBAIR-JAKARTA: Larger and more diverse cities are a sign of Asia's increasingly dynamic economies. Yet this growth has come at a cost. Swelling urban populations and increased concentration of industry and automobile traffic in and around cities has resulted in severe air pollution. Emissions from automobiles and factories; domestic heating, cooking, and refuse burning are threatening the well being of city dwellers, imposing not just a direct economic cost by impacting human health but also threatening long-term productivity. Governments, businesses, and communities face the daunting yet urgent task of improving their environment and preventing further air quality deterioration. Urban Air Quality Management Strategy or URBAIR, aims to assist in the design and implementation of policies, monitoring, and management tools to restore air quality in the major Asian metropolitan areas. At several workshops and working group meetings, representatives of government, industry and non-government organizations, and international and local experts and researchers reviewed air quality data and designed action plans. These plans take into account economic costs and benefits of air pollution abatement measures. This report focuses on the development of an air quality management system for Jakarta and the action plan that resulted from the development of this strategy. THE DEVELOPMENT OF JAKARTA Jakarta's population doubled between 1981 and 1991. In 1995, the metropolitan area's population was 11.5 million. This growth was accompanied by a tremendous rise in the number of vehicles on Jakarta's roads, from approximately 900,000 to 1,700,000. From 1965 to 1990, the growth rate of gross national product per capita (4.5 percent) was among the highest in developing countries. Industrial development in the Jabotabek region, especially along the main highways, has been remarkable. These developments are reflected in the city's deteriorated air quality. Pollutant concentrations near the main roads and in the northern part of the urban area are sometimes extremely high. The highest values have been measured in the northern part of Jakarta, but many stations seem to be influenced by local sources. The bus terminals in Pulo Gadung and Cililitan both show average total suspended particles (TSP) values above 300 Vg/m3. Overall, traffic and industries are the main sources of air pollution in Jakarta. Total TSP emissions in Jakarta are estimated at 96,733 tons/year. Particulate matter of 10 microns or less (PM1o ) emissions total 41,369 tons/year, and nitrogen oxide (NOx) emissions are estimated at 43,031 tons/year. TSP concentrations are lower in the outskirts, averaging 100-150 ,ug/m3. The annual TSP averages in the most polluted areas are 5-6 times the national air quality guideline. Resuspension from roads, 1 2 Background Information diesel and gasoline vehicle emission, and domestic wood and refuse burning are the main sources of particulate pollution. Drivers, roadside residents and those who live near large sources are most severly affected. High ozone concentrations, measured 30 to 40 kilometers outside Jakarta, indicate that secondary pollutants have developed as a result of NO, and VOC emissions in Jakarta. SO2 pollution is not as serious an issue as particulate pollution. While attaching an economic value to morbidity and mortality stemming from air pollution can be difficult, there is anecdotal as well as estimated evidence to suggest that the health of Jakarta's residents is under assault. Dose response equations used for valuing health impacts reveal that PMIO caused a total of 4,364 excess deaths, 32 million restricted activity days (RAD), 101 million respiratory symptom days (RSD), innumerable emergency room visits, asthma attacks, cases of bronchitis in children, and hospital admissions, at a total cost of about US$300,000 (based on Indonesian data) in 1990. THE CONCEPT OF AIR QUALITY MANAGEMENT SYSTEM Assessment and control of pollution form two Figure ES.1: Air Quality Management System prongs of an air quality management system (AQMS). These Dispersion Monitoring components are inputs md/ into a cost-benefit analysis. Air quality Air Quality guidelines or standards, Airpoution and economic concentrations objectives and constraints also guide _ the cost-benefit Abatement Control Epse the cost ~~~~~~measures & options S_mn calculation (See Figure regulations ES.1). An action plan rglto contains the optimum Damag set of short-, medium-, Cost analysis assessment and long-term abatement control measures. Successful, air quality management requires the establishment of an integrated system. Such a system involves: * inventorying air pollution activities and emissions; * monitoring air pollution and dispersion parameters; * calculating air pollution concentrations by dispersion models; * inventorying population, building materials and proposed urban development; * calculating the effect of abatement/control measures, and * establishing/improving air pollution regulations. URBAIR-Jakarta 3 In order to ensure that an AQMS is having the desired impact, it is also necessary to carry out surveillance and monitoring. This requires the establishment of an Air Quality Information System (AQIS) that can keep the authorities and the general public well informed about the quality of air, assess the results of abatement measures, and provide continuous feedback to the abatement strategy process. ABATEMENT MEASURES AND ACTION PLAN Car traffic is the most important source for NO, and TSP pollution in the urban center. In the industrial area east and north of the city center, industries may be the most notable sources for local air pollution. Measures to reduce air pollution in Jakarta focus on the transport sector. This is because traffic emissions are a clear and major source of air pollution and measures to address other pollution sources could not be substantiated due to lack of data. While pollution control in industrial areas has not been discussed at length, it must also be promoted through enforcement and regulation. Based on these abatement measures, an action plan was designed through a consultative process that included Jakarta URBAIR working groups, local and international consultants. The measures which stand out from a cost-benefit perspective are introduction of low-lead gasoline and introduction of low-smoke lubricating oil, as noted in Table ES.1 It is proposed that the following technical and policy measures be given priority. * Address gross polluters. Reinforce the anti-smoke belching program. Existing smoke opacity regulations should be more strictly enforced. The success of this action depends upon the routine maintenance and adjustment of engines. * Improve diesel quality. Domestic refineries could be modified to produce low-sulfur diesel (0.2 percent), or it could be imported. Economic instruments such as taxes and subsidies can be used to differentiate fuel price according to quality. Table ES.]: A summary of technical measures, their effectiveness, annual costs, selected health benefits and total valued benefits Technical Measures Avoided Costs Mortality Avoided Avoided health emissions (Annual) benefit number damage (PM,0 (billion Rp) (number of RSD (billion Rp) (tons) of cases) (million) Lowest estimate. Low -lead and unleaded fuel 50 310 300 Address excessively polluting vehicles 1,000 163 3.8 23.7 Inspection & maintenance scheme 1,300 (max) 67 212 5 31 Low-smoke lubricating oil in two-stroke engines 1,350 2-10 220 5 32 Clean vehicle standards-cars with four-stroke 900 18 147 3.4 21.3 gasoline engines Adopt clean vehicle standards for vehicles with two- 2,000 67 325 7.6 47 stroke engines Improving diesel quality 230 41 1 5.9 LNG to replace 50% of gasoline consumption 650 98 2 14.2 4 Background Information * Inspection and maintenance of vehicles. Annual or biannual inspections are necessary to enforce clean vehicle standards. These can be carried out by government or private entities. * Clean vehicle emissions standards: State-of-the-art emissions standards should be set for new gasoline cars, diesel vehicles, and motorcycles. Lead-free gasoline, a requirement for this standard, should be cheaper than leaded gasoline. * Cleanerfuel oil: A reduction in the sulfur content of heavy fuel oil, initially to 2 percent, is a prerequisite. * Awareness raising: Public awareness and participation are key to bringing about policy change. Widespread environmental education promotes understanding of linkages between pollution and health and encourages public involvement. Private sector participation through innovative schemes like accepting delivery only from trucks that meet government emissions standards; Adopt-a-Street campaigns, and air quality monitoring displays should be encouraged. Media can also participate in awareness raising by disseminating air pollution- related data. RECOMMENDATIONS FOR STRENGTHENING AIR QUALITY MONITORING AND INSTITUTIONS It is important to ensure that institutions dealing with air quality be strengthened through clearer mandates and enforcing powers. A single coordinating institution with a clear mandate and sufficient resources must be made responsible for air quality management. A comprehensive AQMS can only be based on sound knowledge. In order to improve data, it is recommended that there be continuous, long-term monitoring at 5 or more city background sites, covering areas of typical and maximum concentrations; 1 to 3 traffic exposed sites to monitor street level pollution; and 1 to 5 industrial hot spots, and continuous monitors for PM,( , CO, NOR, SO2, 03, depending upon the site. Also, an on-line data retrieval system directly linked to a laboratory database either via modem or fax is recommended for modem surveillance. Clearly, environmental risks are escalating. If pollution sources are allowed to grow unchecked the economic costs of productivity lost to health problems and congestion will escalate. While working with sparse and often unreliable data, this report sets out a preliminary plan that has the potential to improve air quality and better manage the AQMS in the future. 1. BACKGROUND INFORMATION SCOPE OF THE STUDY1 This city specific report on air quality management for Jakarta was produced as part of the URBAIR program. A major objective of URBAIR is to develop air quality management systems (AQMS) and action plans in Asia's cities. The AQMS is based on a cost-benefit analysis of proposed actions and measures for air pollution abatement. Costs relate to abatement measures while benefits include a potential reduction in the costs of health damage estimates resulting from air pollution. This study emphasizes the damage to the health of those who are exposed to air pollution. The population exposure is based on measured and calculated concentrations of air pollution through emissions inventories and dispersion modeling . A general strategy for AQMS is described in the URBAIR Guidebook on Air Quality Management Strategy, published by MEIP. Reports based on city specific analysis are produced for each of the four URBAIR/MEIP cities: Jakarta, Greater Mumbai, Metro Manila and the Kathmandu Valley. These four reports outline action plans for air quality improvement, including estimates of cost and benefit figures. The action plans are based on a comprehensive list of proposed measures and actions developed by local working groups in consultation with outside experts. GENERAL DESCRIPTION OF JAKARTA Jakarta is situated on the northern coast of Java Island, around the mouth of the Ciliwung river, at about 1060 east, and 60 south. It covers an area of approximately 665 square kilometers Along the coast, the landscape is very flat with a mean elevation of seven meters above sea level. The southern area of Jakarta is slightly undulating with ground elevation of approximately 50 meters above sea level. Further south in Bogor outside Jakarta, the mountains are as high as 3,000 meters. There are no natural topographical barriers near Jakarta. Jakarta is predominately a city of one or two-story buildings, with high-rises concentrated in corridors along the main roads. This may easily change with continued economic development. Except as indicated, "dollars" refers to 1992-93 U.S. dollars. Except as indicated, all figures, tables, and textboxes were created by the authors for this report. 5 6 Background Information The construction of more high-rise buildings may alter the micro-climate at street level. Air pollution from rush-hour traffic is already a problem, and it is likely to worsen in the future. DKI Jakarta (a commonly used acronym for Daerah Khusus Ibukota Jakarta, or the Special District of the capital city Jakarta) is part of the greater Jabotabek (Jakarta, Bogor, Tangerang and Bekasi) area. At present, there are five mayoralties in Jakarta which are subdivided into 74 subdistricts (kelurahan). Figure 1.1 shows a map of Jakarta. While the work on air pollution concentrates on Jakarta, an emissions survey must account for activities in the surrounding region. North Jakarta covers the areas along the coast. Despite the risk of floods and poor sanitation, residential developments are common in this area. A new town has emerged around the old international airport at Kemayoran. The areas around Tanjung Priok Harbor have a high population density. Rapid residential development is anticipated here, particularly for middle- and lower-income groups. The eastern part is slowly growing and is dominated by marsh lands and paddy fields with a population density of about 24 inhabitants per hectare. Central Jakarta is characterized by government offices and related service sectors. Commercial and trading areas are located south of Central Jakarta, along the roads that serve as main transportation axes. The southern part of Central Jakarta has been growing and developing rapidly during the last 20 years, especially as a medium- and high-income residential area. The northern part of Central Jakarta is very densely populated and has up to 500 inhabitants per hectare. A mostly low-income population lives in the kampong (low-rise, generally unplanned, mostly low- cost residential areas). East Jakarta has a lower population density, but new industrial zones in the Bekasi region may encourage development and urban growth. West Jakarta has soil, ground water and structural conditions appropriate for residential development. South Jakarta has a lower population density. The area has been designated as a ground water percolation area for recharging Jakarta's ground water reserve. The control and management of the greenbelt area competes with the rising demand for housing and commercial use. DATA SOURCES Previous studies The air pollution situation in Jakarta has been studied by several groups and institutions. Studies that have formed part of the background for URBAIR work include: * Indonesia: Energy and the Environment (World Bank, 1993); * Third Jabotabek Urban Development Project (JUDP III), (BAPEDAL, 1994); * Collection of data for the URBAIR study in Jakarta (Soedomo, 1993); * List of 100 industries which may qualify for assistance (COWI consultant/World Bank, 1992); * LLAJR Air Pollution monitoring and control project (Bachrun et al., 1991); URBAIR-Jakarta 7 Figure 1.1: DKI Jakarta with 5 mayoralties UaRA JAKARTA UTARA/ JAKARTA,BARAT/ North Jakarta West Jakarta ( 7 Kecamatan) ( 8 Kecamatan) JAKARTA PUSAT/ r----- JAKARTA TIMUR/ Central Jakarta L.-J East Jakarta (8 Kecamatan) (10 Kecamatan) riZJ -- JAKARTA SELATAN/ South Jakarta. (10 Kecamatan) Source: Jakarta Capital City Govemment 8 Background Information * Environmental impacts of energy strategies for Indonesia (BPPT/KFA, 1992); * Annual report on air quality monitoring and studies (EMC, 1994); * Air Quality Assessment in Medan (Bosch, 1991); and * Jakarta in figures (JSO, 1991). URBAIR data collection Data on population, pollution sources, dispersion, air quality, and health aspects were collected beginning in March 1992. Dr. Moestikahadi Soedomo and colleagues from the Institute of Technology in Bandung, collected data on air pollution concentrations, fuel and traffic, emissions, and meteorological conditions. Dr. Umar F. Achmadi (Faculty of Public Health), University of Indonesia in Jakarta, collected, evaluated, and summarized data on health statistics and costs related to disease and treatment. Project description for this data is in Appendix 9. DEVELOPMENT OF JAKARTA, 1981-1992 Figure 1.2 summarizes available data regarding population, vehicles, fuel consumption, air quality, and economic development over the last decade. As can be seen, data are not available on all items for the entire decade. The data shown and summarized here are described in greater detail in subsequent chapters. Population has doubled in the last two decades, and there is a significant potential for further growth. This is true for Jakarta and the entire Jabotabek region. The number of cars has also doubled in the last 10 years. Consumption of gasoline has grown with the increased car traffic. The consumption of other fuel types does not show a well-specified trend. Industrial areas have emerged in Pulo Gadung, Cipinang and Mookevart, along the main roads towards Bogor, Bekasi, and Tangerang, respectively. The same regulations apply to all industries in the Jabotabek region. In 1990 the GNP/capita for Indonesia was US$570. Between 1965 and 1990, the growth rate of GNP/capita was 4.5 percent, among the highest in developing countries. Three agencies have been operating monitoring networks in Jakarta, taking 24-hours samples at different intervals, measuring TSP, SO2 (sulfur dioxide), NOX, CO (carbon monoxide) and 03 (ozone). SO2 values are low and declining. TSP is the most substantial pollution component in the area. Concentrations of TSP were increasing until 1990, after which the trend has been more variable. The quality of the NO, measurements seems to vary significantly with yearly differences that are difficult to explain. Results from the new monitoring station at JI. M.H. Thamrin indicate that the 24-hour NO, data from other stations may be too low, especially at the more centrally located stations. POPULATION The population in Jakarta has increased about 50 percent from 1981 to 1991, and further population growth and economic development can be expected in coming years. URBAIR-Jakarta 9 Figure 1.2: Development in Jakarta, 1981-93; population, vehicle fleet, fuel consumption and air quality PCp. NCR 12000 .10000 4 000 8000. tL 0 81 82 83 84 85 88 87 88 a8 90 91 92 88 1800 -U MCIC Buse [J4T E cars 1600 1400- + saSee/o §1200 1000 , i . 600 400 200 0* I i I I I I I 81 82 83 84 85 86 87 88 89 90 91 92 93 35D. Gas(103) r 2500 .12000Kwo 2 1500 d d -5000 81 82 83 84 85 8s 87 88 89 90 91 82 98 800 Pasar tkan 500 -a-Bander 400 - PaswSerne - ~Pawa Baru 3W a. -*- angjga Bow 200 ciliIha 100 PuboGadujng 81 82 83 84 85 86 87 a8 89 90 91 92 98 10 Background Information Immigrants mainly settle in the southern and eastern parts of Jakarta. Population increase is mainly due to the high birth rate Table 1.1: Age within Jakarta. Table 1. 1 shows the age distribution in Jakarta in distribution, 1990 1990, indicating a considerable potential for growth. Age % Age % 0-4 12.1 40-44 4.7 5-9 10.4 45-49 3.9 10-14 10.2 50-54 3.0 VEHICLE FLEET 15-19 9.8 55-59 2.1 VEHICLE FLEET 20-24 12.2 60-64 1.5 25-29 12.2 65-69 1.0 Jakarta's vehicle fleet is composed of the following: 30-34 9.5 70-74 0.5 * passenger cars; 35-39 6.3 >75 0.4 * utility vehicles, pick-ups etc.; * trucks and buses; and, * motorcycles and tricycles (Bajaj). Table 1.2: Estimated traffic in In 1981, 56.6 percent of the vehicles were distance traveledfor each of the motorcycles and tricycles, as compared to 50.5 percent vehicle categories (106 km/year) in 1990. Of the vehicle fleet in 1990, 9.9 percent were Gasoline Diesel buses, 28 percent were passenger cars, and I 1 percent Passenger cars 5,900 1,500 were cargo cars. Utility vehicles 300 300 Table 1.2 shows the estimated yearly traffic in Trucks and buses 300 850 distance traveled for each of these categories, using Motorcycles & tricycles 5,300 gasoline or diesel. INDUSTRIAL SOURCES Jakarta has a large and diversified industrial structure. Table 1.3: Number of establishments and persons engaged Although there are various in production in large and medium factories, 1989 estimates for industrial Establishments Prod. workers emissions, they are not Food, beverage. & tobacco 222 14,724 sufficiently specific, and further Textile 717 87,620 work needs to be done in order Wood and wood products 131 9,250 to evaluate the impact of Paper and paper products 193 14,684 to evaluate the lmpact of Industrial chemicals 380 36,022 industries on air quality. Nonmetallic minerals 38 8,884 Table 1.3 shows the number Iron & steel basic industries 17 2,796 of establishments and the Fabricated mineral products 361 54,471 number of employees engaged in Other manufacture 41 3,745 production in various industries. Total 2,100 232,196 Source: Jakarta In Figures (1991). URBAIR-Jakarta 1 1 FUEL CONSUMPTION Data on sales of oil and gas by type of fuel Table 1.4: Petroleum products sold in 1990 (Unit: 103 m3.) are provided in Super 98 Premium Kerosene Solar Diesel Fuel oil Gas Table 1.4. Total 105 1,070 915 1,047 295 1,202 226,000 In addition, 56 tons Industry 21 24 441 153 - 63,000 of coal, and 2,560 tons Domestic 896 606 142 1,202 163,000 of coke were used by Source: Jakarta in Figures (1991). industry in 1989. Three electric power stations use gas and diesel oil for generating electricity, with a yearly production of 9 x 109 kilowatt-hours in 1990. 2. AIR QUALITY ASSESSMENT This chapter provides estimates of the population's exposure to area air pollutants, and quantifies the contribution of different pollution sources to this exposure. Population exposure is estimated by describing existing air pollution concentration measurements and their variation in time and space; making an inventory of air pollution sources and their relative contributions; calculating the concentration distributions using dispersion modeling and calculating population exposure by combining spatial distributions of population and concentrations, and incorporating exposure on roads and in industrial areas. AIR POLLUTION CONCENTRATIONS Overview of database Air pollution measurement programs reveal that Jakarta has a substantial particle pollution problem. TSP air quality guidelines are frequently and spatially extended. According to measurements, the SO2 pollution problem appears to be less pronounced. Monitoring networks, and the results of measurements are described in greater detail in Appendix 1. The monitoring networks which have provided data on which our assessments are based are shown in Figure 2.1. * Seven permanent stations run by BMG (Meteorological and Geophysical Agency). The first BMG station has been in operation since 1976. It is located at the BMG headquarters in Central Jakarta. Six other BMG stations were started in 1980/81, but not operational until the late 1980s. These six stations were restarted in 1991. At the BMG headquarters, TSP, NO, and SO2 are measured, while only TSP is measured at the other six BMG stations. At the BMG stations there is one 24-hour measurement every sixth day. * Two permanent stations run by the Jakarta Municipal Government (JMG), and by the Ministry of Health before 1980. These are part of the United Nations Global Environment Monitoring System (GEMS). At the GEMS sites, TSP, NO, and SO2 are monitored every sixth day. 13 14 Air Quality Assessment Figure 2.1: Air quality monitoring networks in Jakarta .9 Stations operated by BMGo2 lm B. Glodok Stations operated by DKI KPPL C. BMG Headquarter 1. Pasar Ikan D. T. Monas 2. Bandengan Utara E. Halim Perdana 3. Mangga Besar F. Bandengan 4. Pasar Baru G. Ciledug 5. Pasar Senen 6. Pulo Gadung (bus terminal) Stations operated by JMG 7. Cililitan H. Jl M.H. Thamrin 8. Tebet I. Kayu Manis 9. Pondok Gede J. PuloGadung (PT. JIEP) 10. Radio Dalam Note: Positions of Ciledug and Bandengan Utara are uncertain. $ource: Jakarta Capital City Government URBAIR-Jakarta 15 * Eight rotational stations run by DKI KPPL2 (District of Jakarta-Research Centre for Urban Development). Measurements at the KPPL sites are dictated by the availability of equipment and resources. The monitoring stations are operated on a rotational basis. Four stations are operated for eight days and then the equipment is moved to the other four stations. These stations operate for eight months each year. TSP and CO (and sometimes oxidants) are measured at all sites. * Since April 1992, one-hour averages of SO2, NO, NO2, CO and PM,( have been measured continuously at JI M.H. Thamrin in Central Jakarta. This information has not been analyzed in detail here, although reference is made to preliminary findings. Total suspendedparticles measurements Indonesia has adopted the upper limit of World Health Organization air quality guidelines (WHO AQG) as the national standard (see Appendix 2) for TSP. The WHO AQG are 60-90 pg/m3 as the long-term (annual) average, and 150-230 pg/M3 as short-term (24-hour) average. As shown in Figure 2.2, and in Appendix 1, these values are clearly exceeded at the measurement stations in Jakarta. The figure shows averages for the period 1986-92. The highest values are measured in the northern part of Jakarta, but many stations seem to be influenced by local sources. The bus terminals in Pulo Gadung and Cililitan both show average values above 300 pg/M3. TSP concentrations are lower in the outskirts, averaging 100-150 pg/M3. The annual TSP averages in the most polluted areas are 5-6 times the national air quality standard. Very high, 24-hour average values are recorded at all stations. Except for two extreme values, 864 pg/m3 at Bandengan (possibly due to some extreme local sources influence), the maximum values are about 300-450 pg/M3, up to twice the AQG value at several stations. Fluctuations in daily measurements reflect variations in meteorological conditions. While detailed data are not available, it is expected that TSP concentrations are reduced during rainy periods and when the dispersion conditions are good (high wind speed and good vertical mixing). Decreased resuspension from the ground during wet and rainy weather; increased washout of particles during rain, and/or increased wind speed and turbulence with improved dispersion also result in smaller TSP concentrations. Table 2.1: Comparison of annual NO,: averages for 1986-1991 at BMG and Nitrogen oxides measurements Health Air Monitoying Stations NOx (parts per billion) Nitrogen oxides (NO, )data for KPPL and Year BMG-HQ Health monitoring stations BMG/health stations are presented in Table 2. 1. Kayu Manis Pulo Gadung The JMG (GEMS) reported annual mean NO, 1986 60 20 21 concentrations of 2-4 pAg/M3, and maximum 24- 1987 130 18 15 hour concentrations of 5-10 pg/m3 during 1986- 1988 140 12 10 1989. These stations primarily reflect suburban 1990 40 10 9 ambient air pollution. 1991 29 23 23 2 The DKI-KPPL was formerly called DKI-P4L. 16 Air Quality Assessment Figure 2.2: Annual TSP concentrations in Jakarta, 1986-92 (cg/rn3) 424~S. 478ff9\ -2 J ~~~~~0176 t 0252 4030370 t N 0 2 4 km During 1989 and 1990, the average NO, concentration at the Bandengan station in the city center was a low 28 ,ug/m3. NO, concentration measurements taken at DKI-KPPL stations showed a remarkable decline from 113 pg/M3 in 1983, to 9.4 pg/M3 in 1986. Similarly, maximum 24-hour values fell from 395 pg/m3 to 15 pg/M3. This sudden drop in NO, concentrations cannot be explained by the available information. It is likely that aside from a possible improvement in air quality, the siting, sampling or instrumentation of the monitoring stations may have had a major influence (WHO/UNEP, 1992). From 1986/1987 to 1990/1991, DKI-KPPL stations reported an increase in NO, concentrations, while SO2 levels at the same stations fell considerably in the same period. From April to June 1992, NO, NO2 and NO, data from JI M.H. Thamrin showed mean values of 64 ppb NO2 (about 120 pg/m3), and 169 ppb NO, (about 320 ,ug/m3). NO2 daily values ranged from 46 ppb (about 85 pg/M3) to 93 ppb (about 175 pg/M3), higher than the national ambient air quality standard of 150 pg/m3. The highest hourly NO2 values were not far below the 1 -hour proposed national ambient air quality standard of 400 pg/m3. URBAIR-Jakarta 17 Measurements of NO, have probably varied because of changes in measurement techniques. Early results from the BMG sites were high with some monthly averages exceeding 200 jig/M3. At the KPPL sites, the averages for annual measurements of NO, ranged from about 20 to 160 Pg/m3. At the new station at JI M.H. Thamrin, the daily averages have a range of 200-500 jig/m3- The values are much closer to those expected at a high traffic density site rather than those recorded at the network sites. These results, however, are from a very limited data set and longer time series are needed for drawing firm conclusions regarding long-term average values and trends. Ozone measurements Ozone (03 ) has been measured at eight DKI-KPPL stations. In 1986-1987, annual mean 03 concentrations ranged from 2 jig/m3 at the Bandengan location to 15 jig/M3 at the Pasar Senen location. The latter had the highest one-hour concentration of 85.8 jig/m3, while the highest one- hour value at Bandengan was only 8.2 pg/M3. Thus, all reported 03 concentrations in urban Jakarta seem to be well below the proposed national ambient air quality standards. These measurements of 03 levels inside the city are lower than expected, especially compared to the NO, levels. If the 03 levels are correct, the NO, levels should be considerably higher than observed at the long-term stations. On the other hand, high 03 concentrations (above 200 jig/m3) have recently been measured at the Environment Management Centre outside to the southwest to the city (EMC, 1994). Such high concentrations of oxidants may cause eye irritations or acute health effects. Ultraviolet radiation intensity which contributes to photochemical reactions is high in the daytime, especially in the dry season. Therefore, when the supply of the precursor pollutants, NO, and VOC, reaches a high level, photochemical oxidants may be formed and transported across a wide area. The variations in measurements points to the urgent need for a dependable ozone monitoring program in and around Jakarta. Carbon monoxide measurements Carbon monoxide (CO) is measured by the DKI-KPPL network. Average CO levels (8 hour) were around 3.5 mg/m3 in a residential area and at a bus terminal (Cililitan site), but reached 27 mg/m3 at the Glodok station in a central commercial area. This value is well above the WHO AQG and the proposed national ambient air quality standard of 10 mg/m3. It indicates that CO is a problem in heavily traffic-exposed areas. The monitoring station at JI M.H. Thamrin showed daily CO averages of 2.4-5.1 mg/m3 in April-June 1992 (one sample every 7 days). Hourly values on 25 June varied between 0.5 mg/m3 in the night and 8.2 mg/m3 in the afternoon. The highest 8-hour average this day was 7.1 mg/m3, and the daily average values was 4.9 mg/m3. The JI M.H. Thamrin air inlet is 4 meters above ground and about 10 meters from the edge of a highly used traffic circle of about 100-meters diameter. Very high traffic intensity is observed in the circle. Monitoring in a street canyon with heavy traffic probably would give higher CO levels than at the roundabout location. The wind often blows from the station to the traffic circle. 18 Air Quality Assessment Lead measurements Figure 2.3: Particulate lead, annual average, Jakarta Vehicle exhaust is the largest cause of 1991/92 lead pollution. Lead is added to 1.8 gasoline to improve octane. The lead 1.6 content in gasoline in Indonesia is 1.4 - reported to be 0.44 g/l for 88-octane 1.2 - premium, and 94-octane premix WHO Guideline gasoline. Lead-free gasoline was 1.0 introduced in 1995 at a higher price *.8 than leaded gasoline.06 The annual WHO AQG for lead0. averages 0.5-1.0 jig/in3. Figure 2.3 0.4 shows the results of measurements for 0.2 lead in particulate samples from eight 0.2 KPPL sites in 1991/92. The *c 2 t' measurements were made for ten m 0~ ~ ~~~~. months starting in June 1991 and X X X ending in March 1992, for 24 hours every 8th day. Average lead concentrations at the DKI-KPPL stations usually range between 0.5-2 pg/m3. Considering the station locations, lead concentrations well above the proposed national standard of 2 pg/M3 for 24-hour average can be expected in areas exposed to heavy traffic. PMIO samples from JI M.H. Thamrin are analyzed for Pb in Japan. However, no values have been released yet. These values will probably be the best available to evaluate air lead pollution in highly trafficked areas of Jakarta. AIR POLLUTANT EMISSIONS IN JAKARTA Total emissions Data on fuel consumption, traffic and industrial activities were tabulated in the form of an emissions inventory for DKI Jakarta (Table 2.2). Emissions of TSP, PMIo and NO,, have been calculated/estimated. Data on industrial activity, emissions and types of vehicles and distances traveled were scarce. Data on power plant emissions were not available. The database and procedures are described in Appendix 4. Traffic emissions were calculated by using the following method. A main road network for Jakarta was defined from different maps, as shown in Figure 2.4. From a limited set of traffic counts (number of cars per hour), average annual daily traffic (AADT) for some road classes was defined, and data fields with daily traffic was calculated. Traffic counts from 22 different roads (Soedomo, 1993) were used to define a "normalized" traffic composition (Table 2.3). The emission factors used for various modes of transport are shown in Table 2.4. URBAIR-Jakarta 19 Table 2.2: Estimate of total annual TSP, PMIo and NO. emissions in Jakarta, 1990 Emission sources TSP PM1O NOx Note TRANSPORT SECTOR Vehicle exhaust Gasoline vehicle Passenger cars 1,132 1,132 15,279 Pick up etc. 120 120 986 Truck medium 26 26 304 Bus 124 124 1,464 Bajaj 295 295 41 MC 2,219 2,219 311 Sum Gasoline vehicle 3.916 3 98 Diesel vehicles Passenger cars 849 849 1,415 Pick up etc. 329 3,29 511 Truck medium 308 308 2,002 Truck heavy 2 2 13 Bus Coplet etc. 367 367 5,304 Bus regular 602 602 3,913 Sum Diesel vehicle 2.457 2.457 13.15 Sum Resuspension from roads 27.832 d Sum Transport Sector 34,205 13,331 31,543 ~~~~~~~~~~~~~......................... ....................... .............................................................................................................................................................................. :ENERGYlINDUSTRY SECTOR Fuel combustion IndustriaV/commercial. Distillate fuel 185.4 b 92.7 1,483 Coal 0.4 b 0.3 1 Coke 12.5 b 6.2 26 Gas 3.0 3.0 141 Domestic/small industry Fuel oil 1,682.8 a 1,430.4 2,404 Distillate fuel 1,617.0 b 808.5 2,772 Gas 7.8 7.8 365 Open burning 7,027.0 7,027.0 2,635 Sum Fuel combustion 10.535.9 9.375.9 9.827 Industrial processes Food and textile 9,390 d 2,348 Wood and w. products 2,036 c 1,153 Paper and p. products 5,211 c 2,606 Chemicals 3,800 c 1,900 Non met min. prod. 1,710 c 855 Iron and steel 9,450 c 4,725 Sum industrial processes 31.867 13.586 Sum Energy/lndustr!y Sector 42,403 22,962 9,827 ................. ............................. .............. ..................................................................................................................................................................................... OTHER Airports 26 26 661 Construction 20,000 c 5,000 Harbor 100 b 50 1,000 Sum Other 20,126 5,076 1,661 TOTAL 96,734 41,369 43,031 Note: Estimates according to existing data for source groups. a. PM10 = 0.85 . TSP (ref. EPA AP42) b. PM10 = 0.5 - TSP (ref. EPA AP42) c. PM10 = 0.5 - TSP (rough estimate) d. PM10 = 0.25 * TSP (rough estimate) 20 Air Quality Assessment Figure 2.4: Main road network in DKI Jakarta (71a 29$ Source: Jakarta Capital City Govemment URBAIR-Jakarta 21 Some estimates are rough and based on Table 2.3: "Normalized traffic composition"for Jakarta incomplete information. Sedan Pickup Bus Microlet + Truck Truck MC Bajaj While these figures are + Taxi Metro Mini Gandeng often admittedly weak, .5083 .0524 .0216 .0425 .0138 .0002 .3189 .0423 the emissions inventory may be considered adequate for a first estimate of source Table 2.4: Traffic emission contributions and a background for first stage cost-benefit factors analysis. TSP NOx As PMIo is the main harmful component in TSP, the (g/lam) (g/km) exposure calculations are based upon PMIo values. Gasoline Yearly gasoline consumption (Table 2.5) along with Passenger cars 0.2 2.7 traffic count were also used to estimate AADT, giving a total Pick-up etc. 0.33 8 0 Truck medium, bus 0.68 8.0 traffic of 17.2 x lO9 car-km/yr. From this, average emission Bajaj, MC 0.50 0.07 factors of 0.35 g/km of TSP and 2.267 g /km of NOx were Diesel used to calculate area emission fields, as shown in Appendix Passenger cars 0.6 1.0 4. Pick-up etc. 0.9 1.0 Resuspended road dust is added to the Truck, bus 2.0 i3.0 primary emissions from vehicles. A rough Bus, Coplet etc. 0.9 13.0 estimate of road dust resuspension based on Table 2.5: Traffic activity andfuel consumption the following emission factors proposed by data in Jakarta (1990) --JSEPA (EPA, AP 42) is:data in Jakarta (1990) USEPA (EPA, AP 42) is:FulTac - local streets (<500 AADT): 15 g/kr; Ems Fuel Traffic ? collector streets (500-10,000 AADT): Vehicles 10 g/km; Gasoline: cars 967.7 5,659 - major streets (10,000-50,000 AADT): pick-up 66.1 365 4.4 g/km; truck, bus 40.7 221 * freeways/expressways (>50,000 AADT): Bajaj, MC 100.4 5,027 0.35 g/km. Diesel: cars 242.0 1,415 These factors are suggested for dry road truck, bus 867. 155 conditions. Much of the traffic activity in bus, coplet 73.8 709 Jakarta takes place on roads with AADT Fuel consumption greater than 50,000. Assuming that traffic Kerosene, solar etc. 1,773.0 activity share on road classes is 5 percent Fuel oil 1,202.0 (local), 25 percent (collector), 30 percent Coal, coke 2.6 (major), and 40 percent (freeways), and that Gas 226.0 the roads are wet 50 percent of the time, Open buring 878.4 EPA emission factors suggest an average factor of somewhat more than 2 g/km. A recent evaluation, based on road measurements of emission rates, supports the EPA emission factors for paved roads, although the study concludes that more investigation is needed (Claibom et al., 1995). 22 Air Quality Assessment TSP emission Total annual emission of TSP is shown in Table 2.2. Figure 2.5 indicates the following four dominant groups of emissions: * resuspension from road traffic; * industrial processes; * open refuse burning; and, i construction (miscellaneous). Figure 2.5: Total annual emission of TSP from different groups of sources in 1990 (103 kglyr) 35000 30000- -~25000 j20000 .15000 CL 500- 0~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~0 Large point source group resuspension, open refuse burning, and construction are sources that are often omitted in emission estimates. The TSP emission estimate from refuse burning for the Metro Manila study was based on one million households each burning 0.5 kilogram of refuse per day. This is probably an overestimate and will vary with different values for the various regions of the city. There are many construction activities in Jakarta. Since there were no central measurements of this activity which was judged to be much more than Manila or Mumbai, a total emission of 20,000 tons/year was used. This estimate is based on expert opinion and is twice the value that was estimated for Metro Manila. These emissions were distributed spatially according to the traffic distribution since no other information was available. Figure 2.6 shows the spatial distribution of TSP emission in Jakarta. URBAIR-Jakarta 23 Figure 2.6. Spatial distribution of TSP emission in Jakarta (0.1 kg TSP/hr) EMISSIO GR TSP UNIT: KG/H MAX. VALUE IS 2.2027E.02, flY I 18 142 SUKDe 1.10331Ee04 SCALE FACTOR: 1IDE-01 SCALE: GRID SIZE 1500 METER 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 J~~~~~~~2O . . i~~~~~~~~~~~~~~~~~~~~~~~~847' 3z19 .9 19. 191. 220. 81 '78-..108. 65. 323. 75.1548. 976. 207. 763. 41 .Jz18 24. 41. 39. 43. 23. 234. 479. 2W41116\.35G-.246...299:'662. 186. 311.1247. 333. 446. 211. 3. 111~ ~~~~- Jz17 28. 118. 135. 166. 216. 331. 245. 393. 394. 720. 684. 428. 300. 649. 906. 362. 133. 844. 16. 188. .3x16 486. 37. 357. 613. 55. 481. 473. 498. 55.9. 704.1241. 676. 155. 144.1083. 264. 15. 926. 160. 227.1 .3x15 297 42. 226. 288. 62. 151. 377. 462. 750. 302.1088. 976. 440. 408. 845. 595. 627.1105.lD67. 676! J=14 . .91. 148. 292. 331. 530. 519. 594. 460. 787. 759. 577. 751.1072.1245.1433.2203.1652.1555.' .JX13 . %18. 18. 72. 274. 506. 673. 630. 636. 684. 496. 716. 945.1323.1564.1505. 768.40 J=12 . . 198. 72. 128. 170. 560. 432. 898. 492. 687. 577. 1033. 1172. 849. 986. 263. 211. 20. .Jz1 K 176_..192. 241. 214. 403. 689. 545. 740. 460. 486. 440. 400. 269. 165. 195. 64.- .3=10 . . . \111. 110. 376. 724. 485. 695. 755. 590. 716. 855. 519. 553. 238. 73. .7z 9.113. 186. 326. 388. 371. 408. 405. 391. 554. 560. 196. 324-.296-.250. .2 8.137, 208. 280. 329. 249. 481. 121. 346. 334. 282. 12.1 . Jz 7 'y290. 245. 358. 277. 427. 282. 110. 214. 461. 154. 133. Jx 6.132. 1117. 152. 440, 143. 341. 130. 436. 327. 24. 6GA .,z 5.67. 105_ 77. 80. 214. 679. 264. 186. 259. 86. t74. .1z 4.,'32. 59. 227. 96. 457. 213. 275. 12.1 .m3~ 3135. 30. 187. -50. 490. 250. 278. 4. J3z 2.21. 24. 21. - 74. .799. 22. 275. 4. J~~~~~~~~~~ 1.~~~~~~~~~~~~25, 7194.' 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 NO., emission: Data on combustion in mobile and stationary sources have been used to estimate the amounts listed in Table 2.2, and shown in Figure 2.7. Mobile sources. burning gasoline and diesel fuel are the main source group for NO,. Emission of NO,, from industrial processes in Jakarta is not known, but is assumed to be small. 24 Air Quality Assessment Car traffic is the main source of NO, emission. Figure 2.7: Total annual emission of NO,from different groups Process emission from of sources in 1990 (103 kglyr) industry is not considered 20000 an important source. The IBM spatial distribution of NO, ,14000 emission within Jakarta is 12000 shown in Figure 2.8. 8000 E 8000 .. .. 2~~~~~~~~000 , |1 0 Lead emission Larg point sources Diese Ind. proc. The lead (Pb) content in the gasoline consumed in Jakarta in 1990 is calculated in Table 2.6 Table 2.6: Lead content in gasoline Measurements have shown that, in the Super 98 105 x lO' m' x 0.4 kg Pb /m3 =42.0 x 10 Okg course of urban driving, about 35 percent of Premium 1,070 x 10. m. x 0.4 kg Pb/rn =.42.8.0 x. 3 k9 4 .x 105 kg Figure 2.8: Spatial distribution of NO, emission in Jakarta (0.01 kg NO]hr) 1 2 3 4 5 6 7 6 8 10 11 12 13 14 15 16 17 18 18 20 .-=20 _46. 239. . ...106. 0=19 4j. 58. 126. 221. 261. 252.348. 350. t208 . . .1037. 244.1567. 707. 179. 505. 12. J=18 80. 133. 129. 140. 74. 266. 569. 919.2129.1124..789..963.'734. 608.1019.2073. 581. 465. 191. 421 J=17 91. 381. 436. 536. 695. 576. 788. 790.1278.1351.1718.1376. 972.1122.1467.1167. 435. 773. 52. 603. 14 I J=16 580. 121. 304. 513. 180. 576.1530. 1610.1814.2282.4009.2179. 500. 466.2019. 366. 49. 541. 516. 242. J=15 89. 136. 242. 440. 200. 494.1225. 1499.2420. 980.3520.3154.1429. 832.1257. 942.1040.1117.1480. 710. 3=14 . . 283 475. 836.1068.170. 1686.1923. 1480.2544.2457 1868.1447.1986.1568.1683.1237. 929.1103.1 J=13 . . . 61. 61. 235. 888.1644.2177.2049.2052.1721.1605.1340.1582.1820.1624. 945. 523. 317, 0=12 . . .\323. 235. 420. 550.1821.1404.2901,1594.2229.1872.2846.2314.1272.1711. 846. 679. 65. J=11 . . 1 566. 619. 780. 692. 1301.2225.1766.2390.1496. 1583. 1427.1295. 872. 539. 634. 208. J=10 . 361. 361.1214.2333.1566.2251.2445.1915.2314.2752.1673.1780. 769. 235. I= 9 368. 603.1056.1256.1192.1322.1312.1267.1788.1311. 635.tO45.,953. J= . . . . 447. 673. 907.1066. 802.1562. 395.1120. 1081. 06. 38.1 J= 7 .1935. 791.1155. 896.1379. 910. 360. 684.1479. 495. t J= 6 426. 383. 493. 445. 466.1101. 422. 8921.1054. 78. 20' = 5 219. 340. 250. 261. 691. 729. 852. 602. 833. 277. 238. J-= 4. .,103. 193. 735. 313. 497. 201. 884. 39.r = 3 . 54. 113. 97. 603-163. 602. 317. 692. 15. I -. I M AX. VALUE IS .1=3 . . . £s ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~s ~~~4.008GE.01. IN 11. 161 J=- 2 . . . . . . . .69. 79 ,70.237. Q623. 72. 884. 13. . SUM= 2.55184E403 3= I . .. . 6 622. SCALE FACTOR: 1.0E-02 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 SCALE: GRIO SIZE 1500 METER URBAIR-Jakarta 25 the lead is exhausted as particles in the PMIo fraction (Haugsbakk and Larssen, 1985). The exhaust system Table 2.7: Lead emission functions as both a temporary and a permanent In the TSP fraction 353 x IO' kg Pb/year depository. During accelerations, part of the deposited In the PM,, fraction 164 x 13 kg Pb/year lead is exhausted as larger particles. It is generally assumed that about 25 percent of the gasoline lead is permanently deposited in the exhaust system. The emission of lead to air in Jakarta is given in Table 2.7. Industrial emissions containing lead should also be taken into account DISPERSION MODEL CALCULATIONS Dispersion conditions General description of topography and climate in Indonesia. The atmospheric circulation over Indonesia is affected by the meridian circulation termed Hadley circulation or trade wind. When the sun moves toward the southern hemisphere, the northeast trade wind is attracted to the south (September-February), and moist air from the sea influences Jakarta. When the sun moves toward the northern hemisphere, Jakarta is influenced by dry air (June-August). Normally, Indonesia experiences relatively low wind speeds. In the coastal regions of Indonesia, local land and sea breeze may cause stagnation in the air when they are directed opposite the large- scale wind systems. The dispersion of pollutants may, therefore, vary with season and time of day. The topography of Indonesia is dominated by the volcanic belt which runs from the western tip of Sumatra to the eastern Irian Jaya, and from the northern tip of Sulawesi to the southern part. In the western and central parts of Java, the topography plays an important effect on the dis- persion conditions. Indonesia's climate belongs to the tropical maritime continent type, one of the most humid regions of the world. The monthly average relative humidity varies between 70-90 percent at an average temperature of 26-280C. Topography, climate and dispersion conditions in Jakarta. The area around Jakarta is flat, and no local topography affects the dispersion conditions. The climate is hot and humid. Solar heating during the day and the earth cooling during night produces a local land-sea breeze. The Agency of Meteorology and Geophysics (BMG) operates six weather stations in the DKI Jakarta and BOTABEK area. The stations measure: * air temperature; * air humidity; * wind speed; * wind direction; * cloudiness; * barometric pressure; * rainfall; and * number of rainy days. 26 Air Quality Assessment Mixing height is derived from upper air measurement (by means of the rawindsonde) from the Soekamo Hatta International Airport. Two-way frequency distribution of wind speed and direction is derived for the six weather stations in the DKI Jakarta area. The wind is categorized into 8 directions and 4 classes of speed (0; 1-3 knots; 4-6 knots; and greater than 6 knots). Appendix 8 contains a description of dispersion conditions in Jakarta. Yearly data Figure 2.9: Annual wind frequency, BMG, Jakarta from the BMG weather station have been used to calculate annual 25 average concentrations of NO, and TSP. Figure 2.9 shows the 20 occurrence of wind for BMG 15 037 knots-> Jakarta. Where stability data were 14-C knots not available for Jakarta, the 0*4- knots calculations were performed with 10 neutral conditions. The models use 30°-sector averages, and the 5 - - frequency distribution with 8 * wind sectors is transferred to 30°- 0 - _: _ __ sectors. z co co z According to meteorological data (Appendix 8), dispersion conditions in Jakarta are complex, and sharp gradients are found in the wind between the center of the city and the coastline. Thus, it is important to account for the vertical exchange of pollution. There are few high stacks in Jakarta and emissions usually come from low stacks. In such a situation, the spatial distribution of source intensity is nearly proportional to the distribution of concentration values. As an estimate of vertical exchange, neutral stability conditions are used for the mixing layer for the dispersion model. The influence of low weight level sources is probably overestimated in periods with strong solar radiation and underestimated during nighttime. The annual average concentrations may be somewhat overestimated. More accurate dispersion calculations may be carried out using numerical models describing actual dispersion conditions. It is important to use actually measured input data and to control numerical errors. This study has used only statistical distributions of meteorological data. Even for long-term calculations, it is necessary to use hourly meteorological data (wind and stability) to create a joint wind speed/direction/stability matrix. The locations of measurement stations need to be reconsidered because the variation in wind roses among these stations is too great. Adverse meteorological situations in Jakarta. Studies in Jakarta indicate weak and short-lived inversions. During the night, the cooling may produce ground-level inversions that trap the emissions and produce high concentrations. As soon as the sun rises, however, these inversions break up. High ground-level concentrations may also arise when the local land-sea breeze is opposed to the large-scale wind system. This could happen during the early mornings when the sky is clear, and the airmass in the inland is cooled from below by ground infrared radiation. The airmass URBAIR-Jakarta 27 tends to follow the topography towards the coast. In the Jakarta area, the wind follows the river valleys from south to north. The combination of low wind speed and unstable atmospheric conditions in the daytime can lead to high ground-level concentrations near point sources (stack emissions) due to the vertical turbulent motions. Dispersion model calculations Model description. The dispersion modeling in the first phase of URBAIR focuses on the calculation of long-term annual average concentrations within 1.5 x 1.5 km2 grids ("city background" concentrations). Contributions from nearby local sources in specific receptor points such as street sides or industrial hot spots is evaluated separately. The dispersion model used is a multi-source Gaussian model that treats area, point, and volume sources separately. Such a model is adequate for calculating a first approximation of the contribution from various source groups to long-term average air pollution concentrations. Meteorological input to the model is represented by a joint wind speed/direction/stability matrix representing the frequency distributions of these parameters for the calculation period. The dispersion conditions are considered to be spatially uniform over the model area. The wind distribution shown in Figure 2.9 is transferred to 30'sectors, and the calculations are made for neutral stability. For point sources, plume rise (Brigg's equations) is taken into account along with the effects of building turbulence and plume downwash. For area sources, the dispersion of the emissions in a square grid is simulated by 100 ground-level point sources equi-spaced over the square, using the actual effective height of the emissions (for the traffic source, a 2-meter emission height is used).The Brookhaven dispersion parameter classification has been used. The actual software package used in the KILDER model system was developed at NILU (Gram and B0hler, 1993). Secondary particle formation, such as secondary sulfate and organic aerosol, is not taken into account in this modeling exercise, which treats only dispersion of primary emission compounds. Further modeling and particle analysis should be done to estimate the extent of secondary particle formation. TSP. The main contributors of TSP are traffic, industry and domestic burning. Figure 2.10 shows calculated and observed TSP concentrations in Jakarta. Traffic is the most important source and contributes a maximum of 120 [lg/m3 in the center of the city. Of this, resuspension contributes 100-110 ,ug/m3 . The concentration distribution as a result of industrial emissions shows a maximum of 70 ,ug/m3 over the industrial areas in the eastern part of the city. The emission from domestic burning shows a smaller maximum (10- 15 pg/m3) in the suburbs as a result of the population distribution and dispersion conditions. The observed concentrations are inserted in Figure 2.10, showing the total concentrations. An extra-urban background concentration (70 pg/m3) has been added. Generally, the calculated values are lower than the observed TSP values, particularly in the northern part of the city, close to the harbor. Some of the measuring stations are located near streets with high traffic intensity. This may explain some of the discrepancy between observed and calculated concentrations. However, in the northern part it is not possible to explain the observed concentrations by the estimated emissions. In order to improve air quality estimates in the maximum zone, it is 28 Air Quality Assessment necessary to know more about the emissions causing such Figure 2.10: Observed (encircled values) and calculated TSP high TSP values. In this area concentrations in Jakarta (jg/rm3) the observed NO, Trafftc and concentrations are also construction Industry Fuel combustion underestimated. NO,. Each source group's contribution to total NOx 4 0 concentration is shown in / .-' Figure 2.11. An extra-urban k.P background concentration of 15 pg/m3 has been added. Sum In the central and southern parts of Jakarta, there is a reasonable correspondence between observed and calculated concentrations. In the northern part (close to the harbor) and in the eastern part (close to the industrial area), the calculated emissions are below observed concentrations. Measurements from the \60 area indicate that N02 concentrations are 30-50 percent of the NO,, concentrations, and the proposed NO2 air quality standard is not exceeded for yearly average values in Jakarta. The observed ozone concentration in Jakarta is low as a result of the fast chemical reaction with the local NO emission, as shown in the following equation: NO+03 -NO2+02 High 0,, concentrations measured 30-40 km outside Jakarta area indicate that secondary pollutants develop as a result of NO, and volatile organic compounds (VOC) emissions in Jakarta. Further investigations are needed to clarify the extent of these pollution problems. URBAIR-Jakarta 29 Pollution hot spots Figure 2.11: Observed (encircled values) and calculated NO, Pollution hot spots are concentrations in Jakarta (pg NO2jm3) characterized by significant pollution sources that emit Traffic Industry Fuel combustion large concentrations. Such hot spots are located along the main road system; and near industrial areas with ( significant emissions, \ X especially through low stacks. Preliminary calculations of hot spot concentration values Sum indicate that the pollution problem in Jakarta is mainly an urban-scale problem resulting from many distributed sources. Additional pollution along the main roads results from local traffic emissions. POPULATION EXPOSURE TO AIR POLLUTION IN JAKARTA Population exposure is defined as the number of persons experiencing modeled pollution compound concentrations within given concentration ranges. The cumulative population exposure distribution gives the percentage of the total population exposed to concentrations above standard values. People are exposed to air pollutants at home, on roads, at work, and other places. In order to correctly map population exposure, data are needed on: * Concentration distribution, and variation with time in homes (general city air pollution or city background), along the main road network, and near other spots such as industrial areas, and * Population distribution (residences and workplaces), the number of commuters, and their time-dependent travel habits. Databases for population exposure calculations are often incomplete. A methodology must be developed for each city based on the available data. 30 Air Quality Assessment Estimating population exposure in Jakarta Only exposure to TSP has been calculated for Figure 2.12: Long- term average TSP concentration close to Jakarta. A total NO, field road with high traffic intensity (I car/sec = 3,600 cars/hour) as could not be calculated an annual average because of lack of data on NO, emission from TSP (pg/M3). industry. Population 400 - exposure was estimated on the assumption that inhabitants in each grid \ square are exposed to annual average TSP _ concentrations as shown in Figure 2. 1 0. 200- The distribution is adjusted upwards to _ account for all area- distributed sources. TSP 100 concentrations are assumed to decline with increasing distance from 0 I> the road, as shown in 0 50 100 (m) Figure 2.12. The results of TSP exposure calculations are shown in Figure 2.13. The deviation from a log-normal distribution may be due to lack of data for various traffic intensities along the main roads in Jakarta. Values for total exposure and for the effect of a source reduction in pollution on exposure, are given in Table 2.8. This table also shows commuting exposure. It is assumed that 30 percent of the population in each grid square is exposed to road side concentrations for 2 hours each day during commuting. A typical road concentration of 400 p.g/m3 is used for calculating the influence on annual average concentration. Table 2.8: Number of residents in Jakarta exposed to different levels of TSP concentrations outside their homes. Cs [Cl c2 ] Nc > C2 AN P AP Traffic reduction Industry reduction Domestic reduction igIm3 jggm3 inh. % % 25% 50% 25% 50% 25% 50% 80.0 90.0 6,458,608 0 100.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 90.0 100.0 6,454,574 4,034 99.938 0.062 0.225 0.792 0.062 0.314 0.062 0.062 100.0 110.0 6,400,467 54,107 99.100 0.838 1.458 3.741 0.987 1.257 0.838 0.838 110.0 120.0 6,272,124 128,343 97.113 1.987 3.794 11.120 2.494 3.398 2.190 2.439 120.0 130.0 6,024,203 247,921 93.274 3.839 7.485 19.039 4.437 5.806 3.976 4.065 130.0 140.0 5,668,254 355,949 87.763 5.511 11.207 19.477 6.873 8.571 5.170 5.357 140.0 150.0 5,106,759 561,495 79.069 8.694 13.964 30.877 9.416 9.281 8.973 9.366 150.0 160.0 4,454,121 632,638 68.964 10.105 13.167 10.570 11.598 9.683 10.190 11.491 160.0 170.0 3,835,884 618,237 59.392 9.572 13.172 1.774 7.440 9.383 10.115 8.430 70.0 180.0 3,320,573 515,311 51.413 7.979 23.949 0.059 9.870 11.354 7.511 8.270 180.0 190.0 2,478,595 841,978 38.377 13.037 6.219 0.000 9.175 9.476 12.597 11.305 190.0 200.0 1 ,446 275 032,320 22.393 15.984 1.522 0.000 8.926 18.088 18.792 18.792 . 66.........................................................................................................................................................................................:,!'! 200.0 210.0 807,480 638,795 12.502 9.981 0.000 0.000 7.784 4.611 7.083 7.700 210.0 220.0 424,136 383,344 6.567 5.935 0.000 0.000 4.370 3.676 5.935 5.318 220.0 230.0 329,558 94,578 5.103 1.464 0.000 0.000 1.464 0.000 1.464 1.464 230.0 240.0 329,558 0 5.103 0.000 0.000 0.000 0.000 0.000 0.000 0.000 240.0 250.0 329558 0 5.103 0.000 0.000 0.000 0.000 0.000 0.000 0.000 250.0 260.0 329 557 1 5.103 0.000 0.000 0.009 0.000 0.000 0.000 0.000 ............. 260.0 270.0 329,276 281 5.098 0.004 0.015 0.049 0.006 0.012 0.004 0.008 270.0 280.0 328,246 1,030 5.082 0.016 0.055 0.226 0.019 0.039 0.016 0.012 280.0 290.0 325,169 3,077 5.035 0.048 0.130 0.473 0.075 0.069 0.048 0.059 290.0 300.0 317,409 7,760 4.915 0.120 0.296 1.034 0.132 0.169 0.132 0.136 300.0 310.0 304,915 12,494 4.721 0.193 0.482 0.640 0.292 0.337 0.194 0.236 310.0 320.0 283,503 21,412 4.390 0.332 0.620 0.119 0.356 0.523 0.358 0.348 249,940-33,5636 3.870 0-- - -- - - -- - -- - - -- - i- 3 8 -- - -- - - -- - -- - ---0-00i-------------2- 1.378 0.001 0.611 0.629 0.509 0.539 330.0 340.0 203,937 46,003 3.158 0.712 0.679 0.000 0.516 0.609 0.684 0.606 340.0 350.0 125,549 78,388 1.944 1.214 0.172 0.000 1.496 1.510 1.425 1.425 ..9 .........................................................................................................................................................................................................!! 350.0 360.0 73,132 52,417 1.132 0.812 0.000 0.000 0.664 0.573 0.600 0.670 360.0 370.0 14,852 58,280 0.230 0.902 0.000 0.000 0.707 0.633 0.902 0.832 370.0 380.0 0 14,852 0.000 0.230 0.000 0.000 0.230 0.000 0.230 0.230 . . . ... ...................................................................................................... 390.0 49000 0 0 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 390.0 400.0 0 0 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 Cs [C1, C2 ]: concentration interval NC > C2 cumulative concentration dist. AN: number of people in each pollution P: cumulative concentration distribution in percent of total population. AP: percentage of population in each concentration interval. Emission reduction: Percentage of population in each concentration interval after emission reduction. Ul 32 Air Quality Assessment AIR QUALITY ASSESSMENT Figure 2.13: Percentage of population exposed to annual average TSP- SUMMARY concentrations above different values, as given along the x-axis Concentrations of TSP have been Population (%Yo) 99.9 measured regularly at 17 fixed locations, a few days per 99x month. Some of the stations are located along streets, others in representative 90- regions, and some in 80- industrial areas. This 8 limited data base shows the following: 5 3 TSP is the most _ X important pollutant in Jakarta. * Observed TSP 10- concentrations 5 - \ frequently exceed AQG. Concentrations 1 near the main roads, and in the northern part of >// - > the urban area, 50 100 200 300 400 TSP (pg/M3) are sometimes extremely high. * Measurements in industrial areas indicate high TSP concentrations. * High 03 concentrations, measured 30-40 kilometers outside Jakarta, indicate that secondary pollutants develop as a result of NO, and VOC emissions in Jakarta. Further investigations are urgently needed to clarify the extent of these pollution problems. Emission sources. Rough estimates of TSP emission in Jakarta indicate that a considerable part of total emissions comes from car traffic, industrial processes, and open burning. Estimates are based on statistical data on pollution-producing activities, and on emission factors for the Jakarta region. Further investigation is vitally important to improve these rough estimates and to the development of a control strategy. Road traffic is the main source of NO, emission. In this study, data to estimate NO, emission from industry were not available. Industrial process emissions of NO, should be estimated to get a complete picture. However, these emissions are expected to be less important than traffic emissions. URBAIR-Jakarta 33 Population exposure. The number of residents exposed to different TSP or PM1O levels is used to calculate health impacts of air pollution. The WHO AQG for particulates is exceeded for all residents in Jakarta. For each square in the grid, the spatial mean concentration is compared to different concentration levels, counting the number of people exposed to concentration above each level. In addition, several people are exposed to sub-grid exposure from main roads, as shown in the lower part of Table 2.8 and the right part of Figure 2.12. These are drivers (8 hours/day), commuters (1/22 hours/day) and roadside residents (24 hours). Due to the lack of industrial NOX emission data, annual exposure to NOx is not calculated. The observed NOx values suggest that either NOx is not an area problem, or that the measurement or stations are not representative. Appendix 4 shows discrepancies between different sets of population data. For exposure calculations it is essential to have correct data for the population distribution. Background for calculating effects of abatement measures. A simplified procedure for calculating emissions and the effects of different control measures on the emissions has been programmed into spreadsheets. These may be used in combination with population fields to prepare first order estimates of the effects of various abatement measures on exposure distribution. The concentration within a grid element CQ(I, J) will be the sum of the contributions from each source group K: Cs (I, J) = B(I, J) + aK *CK (I,J), where B(I,J) is a background value, CKJIJ) is the concentration contribution from source K, and aK is an emission reduction factor. From this newly calculated concentration distribution, new exposure calculations should be performed, and from these new effects should be calculated. This may also be programmed into spreadsheets AIR QUALITY ASSESSMENT Data shortcomings Monitoring. Measurements should be carried out to specify the typical chemical composition of the particles at the different stations, particularly in air pollution episodes. The human health impact of high TSP concentrations depends on this composition. The profile of chemical components will also help to identify the main source of particle pollution at the monitoring stations. Microscopic investigation of the particle structure may also give important information. This information is needed to develop a cost-effective control strategy. The measurement system in Jakarta has the following features and shortcomings: * collects 24-hour samples of TSP, NO, and SO2; * monitoring network is run by several agencies with different routines for sampling, analysis calibration, and reporting; * detailed station descriptions are needed to control for local influence; * few measurements are taken in the other parts of Jakarta, and 34 Air Quality Assessment * hourly meteorological data (wind, stability etc.) are needed from several places. The monitoring agencies are operating under considerable financial constraints that impact methodological and manpower capacities. It is nevertheless important to improve air quality monitoring in Jabotabek, as the air entering Jakarta comes from the environs. An improved monitoring system should include: * at least 5 city background sites, covering areas of typical and maximum concentrations; * 1-3 traffic exposed sites (to monitor street level pollution); * 1-5 industrial areas and hot spot sites; * continuous monitors for PM1o, CO, NO,, So2, 03, depending upon the site; * an on-line data retrieval system connected to a lab database, via telephone or modem; * a single agency should be responsible for the monitoring and network control; * 03 measurements should be carried out soon in order to determine whether the area has a photochemical air pollution problem and such measurements should be carried out continuously over a one-year period at sites inside and outside Jakarta. Emissions. Spatial investigations should be planned to specify: * industrial emissions (questionnaires and measurements), x open burning, * resuspension, * traffic counting, and * traffic composition. The Japan International Cooperation Agency (JICA) Integrated Air Pollution Study will continue air pollution studies in the Jabotabek area, including the preparation of an improved emissions inventory. This will include emissions from the point sources, as well as better traffic data. Proposed actions to improve the air quality assessment in Jakarta are listed in Table 2.9. URBAIR-Jakarta 35 Table 2.9: Actions and time schedule for improving air quality assessment Actions Time schedule Air Quality Monitoring Design and establish a modified, improved, and extended ambient This activity, part of the JICA study, started in 1995. air monitoring system: * evaluation of sites; number and locations; * selection of parameters, methods, monitors, and operation schedule; * necessary upgrading of laboratory facilities, and manpower capacities. Design and establish Quality Control and Quality Assurance This should start immediately, together with the Systems establishment of an improved monitoring system, and upgraded laboratories. Design and establish an Air Quality Information System, including This should begin as soon as modern, on-line, monitoring * database, stations have been established. * information to - control agencies, I- law makers, . generai pubiic...................................................... Em issions........ ..................................................................................................I....................... Improve emissions inventory This is a part of the JICA study, started in 1995. * Produce inventory of industrial emissions (location, process, Priority: emissions, stack data), industrial emissions inventory; resuspension from - - Improve inventory of road and traffic data, roads; development of an emissions inventory i Improve inventory of domestic emissions procedure; collecting traffic data; classifying the road * Study resuspension from roads, from other surfaces. network. Develop an integrated and comprehensive emissions inventory procedure, include emission factor review, update and QA procedures. Cover entire Jabotabek. mprove methods and capacity for emission measurements. Population exposure Assess current modeling tools/methods, and establish appropriate Begin immediately by establishing a group which will have models for control strategy in Jakarta.. long-term responsibility for performing such modeling . 3. HEALTH IMPACTS OF AIR POLLUTION This chapter presents an overview of the major impacts of air pollution in Jakarta, including an estimation of the monetary value of health damages. Concern about air pollution focuses on the high concentrations of suspended particles and lead, both exceeding national and WHO air quality guidelines (see Chapter 2). Problems arising from SO2, NO,, and ozone (photochemical air pollution) do not appear to be as serious. Therefore, this chapter concentrates on PM1o and lead. Health impact estimates are based on air pollution dose-response research conducted in the United States (Ostro, 1994). The methodology for deriving these estimates is described in the URBAIR Guidebook. The equations presented here are derived from Ostro's research. Guidelines for acceptable pollution concentrations, "no-damage benchmarks," have been proposed by WHO. Although damage to human health is not the only adverse effect of air pollution, the lack of appropriate data prevented the quantification of other impacts such as a reduction in the economic life of capital goods, tourism, crop production, etc. Just to give an indication of the possible damage from traffic congestion, let us suppose that one-third of the population (approximately 9.4 million in 1990) loses an average of two hours per day due to traffic congestion for 250 days per year. With an hourly wage rate of Rp840, this results in a damage of approximately Rpl,316 billion. Figure 3.1: Distribution of exposure of population to PM1O % of population ASSESSING AND 16 VALUING MORTALITY AND MORBIDITY 12 10 Health impacts are divided into 8 mortality (excess 6 deaths) and 4 morbidity (excess cases of illness). 2 Mortality and 0 Iinfhhi morbidity are derived c L C N from air quality data _ N 37 38 Health Impacts of Air Pollution using dose-effect relationships. In principle such relationships are found by statistical comparison of death rates and morbidity in urban areas with different air quality. Ostro (1994) has estimated appropriate dose-effect relations. Admittedly, these dose-effect relations are derived from studies in U.S. cities, and it is speculative to apply them to Jakarta. But until specific dose-effect relations are derived for tropical conditions, these calculations are useful for preliminary analyses. Furthermore, while it is clear that indoor air pollution, such as that caused by cooking, can also damage health, this analysis was limited to outdoor air pollution. Mortality due to PMIo. The relationship between air quality and mortality, where P represents the number of people exposed to a specific concentration; c stands for crude mortality rate (0.007 in Jakarta); and PM,O is the annual average concentration in Pg/rM3, is: Excess death = 0.00112 x ([PM,O] - 41) x P x c The PM,0 benchmark is 41. Above this benchmark mortality increases corresponding to the WHO AQG for long-term annual average concentrations (75 pg/m3), taking into account that PM1o concentrations are 55 percent of the TSP concentrations. From this relationship and the data presented in Chapter 2, it can be concluded that the excess mortality due to PM,( was about 4,500 cases in a population of 9.4 million. Note that mortality is proportional to the population. If the air quality does not deteriorate, the mortality would still increase with population growth. Mortality due to lead. Diastolic blood pressure (DBP) plays a role in the dose-effect function of mortality caused by lead. The relationship between lead concentration and change in DBP is estimated as: A DBP = 2.74 (In [Pb in blood]01d - In [Pb in blood]new), where [Pb in blood] indicates the concentration of lead in blood ([tg/dl). The relationship between lead in blood and lead in air is complex, but generally proportional. A good approximation can be made with the following equation: A DBP = 2.74 (In [PbA],1d - In [PbA]new), where [PbA] indicates the concentration of lead in the air (,ug/m3). Evidence of a threshold level of [PbA] is scant, and the threshold can be taken as zero. However, as per WHO guidelines, a benchmark of 0.5 pg/m3 for [PbA]o,d can be used. If we fill in the existing lead concentration for [PbA]new , the change in DBP can be derived. The change in the 12 year probability of death, Pr(M), related to the change in blood pressure due to lead is estimated as: Pr (M) = (I+ exp-[-5.315 + 0.03516 DBP0IdI)-' -(1+ exp-[-5.315 + 0.03516 DBPnew])-' The reference value of DBPOd is 76, the average value used in the United States. URBAIR-Jakarta 39 The average 24-hours concentrations measured in Jakarta vary between 0.5 and 2.0 pg/M3, but no exact exposure figures could be derived. Therefore, the study used was that by Calkins et al. (1994), who estimated 340 cases of mortality per year due to lead on the basis of the same dose- effect relations. MORBIDITY Particulates. Many cases of chronic bronchitis, restricted activity days (RAD), respiratory hospital diseases (RHD), emergency room visits (ERV), bronchitis, asthma attacks and respiratory symptoms days (RSD) can be attributed to particulate pollution. The following dose-effect relationships, described in greater detail in the URBAIR Guidebook, are used: * Change in RAD per person per year per pg/in3 PMIo is estimated at 0.0575. Using the WHO AQG, the change is 0.0575 x ([PM,0] - 41). * Change in RHD per 100,000 persons is estimated at 1.2 per pg/m3 PMIo. Using the WHO AQG, RHD per 100,000 persons are estimated at 1.2 x ([PMIo] - 41). * Change in the number of ERV per 100,000 persons is estimated at 23.54 per pg/m3 PM1o and the total number of ERV per 100,000 persons at 23.54 x ([PM10] - 41). * Change in the annual risk of bronchitis in children below 18 years, who comprise 35 percent of the total population (Achmadi, 1994), is estimated as 0.00169 x ([PM,0] - 41). * Change in daily asthma attacks per asthmatic person who total 7 percent of the population (Achmadi, 1994) is estimated at 0.0326 x ([PM,0] - 41). * Number of RSD per person, per year, is estimated at 0.183 x ([PM,0] - 41). The impacts of PMIo air pollution, on Table 3.1: Impact of PM1o air pollution on health in Jakarta are summarized in Table 3.1. health, 1990 Type of health impact Number of cases Lead. For practical purposes, the WHO AQG (thousands)* for lead exposure thresholds may be used. The Restricted activity days (RAD) 32,001 major effects of lead are hypertension, Emergency room visits (ERV) 131 coronary heart disease, and decline of Bronchitis in children 326 intelligence quotient (IQ) in children. Respiratory symptom days (RSD) 102,000 Respiratory hospital admissions (RHD) 7 The relationship between a change in the * Figures are presented in detail for reasons of consistency, probability of hypertension and a change in air not to suggest large reliability. quality is estimated as follows: A H =(1 + exp - (- 2.744+ 0.793 In 2[PbA]1))-' -(1 + exp - (- 2.744 + 0.793 In 2[PbA]2))-J in which [PbA]2 is the ambient lead concentration in the air. As [PbA],, the WHO AQG of 0.5 ptg/M3 can be used. The dose-effect relationship of coronary heart disease (CHD), where the increase in the 10 years probability of a case is A Pr (CHD) is: 40 Health Impacts of Air Pollution A Pr (CHD) =(J + exp-(-4.996+0.030365 DBPj))-J -(l +exp-(- 4.996+ 0.030365 DBP2))-1 The dose-effect relationship used for estimating a decline in children's IQs is: A IQ = 0.975 x ([PbA]2 - [PbA]f), The WHO AQG of 0.5 pg/m3 is used for [PbA]h Because of Table 3.2: Health impact of The ~~~~~~~~~~~~~~~~~~lead air poll~ution ((11992) lack of exposure figures on lead, we use the results of lead ar dion (1992) Calkins et al. (1994), which are based on the same dose- Coronary heart disease 350 cases effect relationships. These results are given in Table 3.2. Hypertension 300,000 points VALUATION OF HEALTH IMPACTS Mortality. Placing a monetary value on mortality is debatable. Many argue that such a valuation cannot be made on ethical grounds. By deleting mortality, however, we would seriously underestimate the total damage caused by air pollution. A case (single instance) of mortality can be valued in two ways. The first is based on "willingness to pay," the other on "income potential." The "willingness to pay" (WTP) approach is described in detail in the URBAIR Guidebook. In the United States, a value of about US$3 million per statistical life is often used. Although such a valuation is not readily transferable from one country to another, an approximation can be derived by correcting the U.S. figure by a purchasing power parity factor. The purchasing power parity in Indonesia divided by the purchasing power parity in the United States is factored as 2,120 divided by 21,900 equaling 0.096 (Dikhanov). At an exchange rate of US$1.00 equals Rp2,233, this results in a value of Rp650 million per statistical life in Indonesia. The second approach is based on income lost due to mortality. The value of a statistical life (VSL) s estimated as the discounted value of expected future income at the average age. If the average age of population is 26 years and the life expectancy at birth is 65 years, the value is: 38 VSL= Xw/(l+d)t t=O In this equation, w equals average annual income, d equals discount rate (Shin et al., 1992). In this approach, the value of persons without a salary (e.g. housewives) is the same as the value of those with a salary. If we estimate the daily wage in Jakarta as Rp6,700 (US$3.00) at 200 working days in a year, w equals Rpl,340,000. At a discount rate of 5 percent, VSL equals Rp23.45 million. In both approaches to the valuation of premature death due to PM1o air pollution, the cost of air pollution in 1990 ranges from Rp2,836 billion to RplO2 billion. Morbidity. The URBAIR Guidebook presents estimated costs of morbidity (medical treatment, lost earnings) based on U.S. values. In order to obtain city-specific figures, the U.S. estimates were corrected by a factor of 0.096 to reflect the difference in purchasing power. These estimates are URBAIR-Jakarta 41 supplemented by estimates created specifically for Jakarta (Achmadi, 1994). Both sets of data are presented in Table 3.3. Table 3.3: Health impacts from PM1O and lead and their valuation in Jakarta (1990) Health impact Cases Specific value Total value Specific value Total value (US-derived) (US-derived) Indonesian based on Indonesian data. (Rupiahs) (million Rp) Rupiahs (million Rp) Impacts from PM10 Mortality 4,364 650 million 2,836,645 23.45 (million) 102,336 Restricted activity day 32,006,885 12,400 396,885 4,466 142,943 Emergency room visit 131,033 55,300 7,246 11,165 1,463 Bronchitis (children) 326,431 70,000 22,850 22,330 7,289 Asthma attacks 1,270,255 21,400 27,183 11,165 14,182 Respiratory symptoms days 101,865,393 3,200 325,969 4,466 454,931 Hospital admission 6,680 6 million 40,078 335,000 2,238 Total (PM,0 3,656,858 725,382 Impacts from lead (valued) Mortality 340 650 million 221,000 23.45 million 7,973 Coronary heart disease 350 47,160 17 11,165 4 Hypertension 62,000 10 million 620,000 3,345,000 207,390 iQ points loss 300,000 980,000 294,000 279,125 83,738 Total (lead) 1,135,000 299,000 CONCLUSIONS Air pollution damages not just human health but also materials, vegetation and crops, buildings and monuments, ecosystems, and tourism. Lack of data and methodological problems make it very difficult to place a monetary value on much of this loss. In this report, damage to human health is estimated by using U.S.-based dose-effect relationships. Damage to health consists of mortality and morbidity. Using the human capital approach (i.e. lost earnings due to premature death), the value of a statistical life amounts to Rp23.5 million. Costs of morbidity are relatively more reliable. They consist of foregone wages and costs of medical treatment. The cost of morbidity due to concentrations of PMIo was estimated specifically for Jakarta. This valuation of damage to human health is an underestimation as it does not include the suffering due to illness or premature death. Table 3.4 presents PMIo contributions from various sources and the number of mortality cases and RSD resulting from each of the categories. Total costs are estimated for each category. These figures are approximations based on the Jakarta air quality model. They reflect reduction in health damage, i.e. a benefit, if the emissions from the indicated source were reduced to zero. The health costs are based on Achmadi's 1994 estimates. The damage due to lead is estimated at Rp291 billion (see Table 3.3). Other health damage (e.g. due to ozone, NOx, SO2) could not be estimated due to the lack of exposure figures. 42 Health Impacts of Air Pollution Table 3.4: Air pollution (PM10) impacts attributed to source categories (1990) Source category Emissions (tons) Mortality Respiratory symptom Costs (Rp (cases) days (millions) billion) All sources 42,417 4,364 100.0 725 Gasoline cars (four stroke) 1,284 730 17.0 28 Motorcycles/Bajaj 2,700 1,460 34.0 54 Diesel fueled vehicles 2,363 1,158 27.0 44 Combustion of heavy fuel oil (domestic sources) 1,430 13 0.3 2 Half of process emissionse 7,000 336 8.0 41 * Simplified model used does not allow calculation of total attribution. Benefits of emissions reduction (Table 3.5) are based on estimates of the total annual TSP, PM10 , and NO. emissions (Table 2.2). These results indicate that reducing emissions from traffic and industry should be the first priority. This does not take into account the costs of abatement. Table 3.5: An assessment of the benefits of emissions reduction Source category Emission Emission Avoided Avoided Avoided "Marginal" benefits (Rp reduction reduction mortality RSD health costs million per ton (O) (tons) (million) (Rp billion) reduced) Traffic 25 5,230 854 20 124 24 Industry (process emissions) 25 3,600 600 14 87 24 Diffuse/domestic 25 3,500 26 0.6 3.8 1 Health impacts and associated costs tend to increase as air quality deteriorates. In addition, with population growth in the city, there is a rise in total costs as the health of more people is put at risk. 4. ABATEMENT MEASURES: EFFECTIVENESS AND COSTS INTRODUCTION This chapter presents information about measures for reducing air pollution in Jakarta and for drafting an action plan that would translate these measures into practice. Information is organized by source category: traffic; power plants; fuel combustion other than in power plants; non- combustion sources; construction; and refuse burning. For the main source categories, characteristics of abatement measures are described in terms of: * effectiveness in emissions reduction and reduced exposure impacts in 1995 (according to the methodology used in Table 3.5); the reference data are mortality (4,500 due to PMIo), and number of RSD (100 million); * costs of measures in order to prioritize implementation; * benefits including reduced excess deaths (mortality, reduced number of RSD, and economic benefits); * policy instruments and institutions that may be used to implement the measures; and * term for emissions reduction: short term (2 years), mid-term (2-5 years) , long term (more than 5 years). The list of measures is derived from the information presented by the local working groups, from the URBAIR Guidebook and from earlier plans for addressing pollution in Jakarta. All figures for emissions, costs, and benefits represent annual estimates for 1990, unless otherwise stated. TRAFFIC This section describes the effectiveness (abated emissions) and, to the extent possible, the benefits of measures such as: * introduction of unleaded gasoline; * implementation of a scheme for inspection and maintenance; * addressing excessively polluting vehicles; * improving diesel fuel quality; * improving quality of lubricating oil in two-stroke engines; 43 44 Abatement Measures: Effectiveness and Costs * fuel switching (from diesel/gasoline to LPG/CNG) in the transportation sector; and * adoption of clean vehicle emissions standards. Introduction of low-lead or unleaded gasoline Unleaded gasoline addresses the lead pollution problem and is a prerequisite for the introduction of strict emissions standards. An "intermediate" approach would be to lower the lead content of gasoline. The introduction of unleaded gasoline requires that vehicles with catalytic converters and a separate fuel distribution system that does not mix leaded with unleaded fuel be simultaneously brought into use. Retailers usually sell both leaded and unleaded fuel. Older engines may require leaded fuel because of the material used for valve seats and/or the high RON-number gasoline Effectiveness. Emissions decline and are proportionate to the eventual market shares of unleaded and low-lead gasoline. In case of low-lead gasoline, the reduced emissions are proportionate to the lead content. Costs of the measure. If lead is removed, the gasoline has to be reformulated in order to maintain ignition properties. To obtain gasoline with a sufficiently high RON number, lead may be substituted by oxygenated compounds. MTBE (Methyl tertiary butyl ether) is the preferred substitute. These changes increase production costs, typically by Rp4O-60 per liter gasoline, depending on the local market for refinery products, the required gasoline specifications, and the costs of MTBE (Turner et al., 1993). From Table 2.5 it is inferred that about I billion liters of gasoline is consumed, leading to a cost estimate of Rp5O billion cost for a 100 percent shift to the use of unleaded gasoline. Policy instruments and target groups. Officially lowering the allowed content of lead is the most common way of affecting change. In countries where gasoline is taxed, the taxes on unleaded gasoline are lowered and those on leaded gasoline are increased, so that the net yield for the fiscal authority does not change. The petroleum industry and gasoline distribution firms have to produce Table 4.1: Introduction of low-lead and unleadedfuel and distribute the gasoline. Effectiveness: Depending on the rate of introduction. Costs: Costs at refinery Rp40-60 (per liter unleaded fuel). Term. Unleaded fuel can be made Benefits: Rp300 billion. available at a large scale within Reduction in mortality, 340 cases; five years. The production of low- loss of IQ points (children). lead gasoline is technically Instruments/institutions: New regulation; tax differential. simple. A summary of this Term: Two to five years. abatement measure is given in Target groups: Petroleum industry, firms that sell gasoline. Table 4.1. URBAIR-Jakarta 45 Scheme for inspection and maintenance Effectiveness. Maladjusted fuel injection systems or carburetors and worn-out motor parts pose a threat to traffic safety. They also increase fuel consumption and costs, and lead to large emissions. Semi-annual inspection and maintenance of vehicles would probably result in substantial reductions in PM1O, VOC, and CO. An accurate assessment of emissions reduction associated with an inspection and maintenance scheme requires statistical data on emission characteristics of the Jakarta vehicle fleet relative to its state of maintenance. Such information is not available. It is assumed that the proposed inspection and maintenance scheme would reduce tail pipe emissions of PMIo, VOC, and CO by one-third, as is the case for the World Bank estimate for Manila (Mehta, 1993). Costs of an inspection and maintenance scheme. Jakarta presently lacks the capacity to test all vehicles for emissions. It is estimated that approximately 650 test units are needed to carry out 33 million tests (a 20-minute, biannual procedure). It is suggested that private firms could share the responsibility (Budirahardjo, 1994)3. A similar scheme has been proposed for Manila (Baker et al., 1992). Such a scheme may cost roughly Rp67 billion, or Rp2,200 per test per vehicle owners. A reduction in fuel costs, associated with improved engine performance, would offset the maintenance costs. Policy instruments and target groups. According to Governor Decrees 122 and 1236 (1990), vehicles must comply with standards and an inspection scheme. Emissions are measured Table 4.2: Implementation of an inspection and at road-worthiness inspections maintenance scheme (Decree of the Minister of Effectiveness: 35% reduction, 1,300 tons PM10. Transportation KM 8 of 1989) Costs: Rp67 billion; maintenance costs are expected to be carried out by the Transport & offset by improved fuel efficiency. Highway Department Service Benefits: Reduced mortality, 212; reduced RSD, 5 million; avoided health costs, Rp3O.8 billion; (Budirahardjo, 1994). reduction of CO, VOC emissions; safer automobiles (if roadworthiness is included in the scheme). Term. An inspection and Instruments/institution: Implementation of existing rules; arrangement for maintenance scheme can be involvement of private firms. implemented within 5 years. A Term> .- Two-five years. summary of this measure is given -Target groups: Private sector. in Table 4.2. 3 The scheme would work in the following way: licensed firms perform inspections; authorities spot-check the firms to ensure that inspections are made properly; approved vehicles get a sticker valid for a specific period; drivers have to show a test report upon request; and vehicles are spot-checked by Transport Authority. 46 Abatement Measures: Effectiveness and Costs Address excessively polluting vehicles A fourth of all vehicles are estimated Table 4.3: Excessively polluting vehicles to have excessive emissions. These Effectiveness: 1,000 tons PM10 vehicles are badly maintained, use Costs: Varies depending on implementation. worn out engines, or have Benefits: Reduced mortality, 163; reduced RSD, 4 maladjusted engine controls. The million; avoided health costs, Rp23.7 billion Instrument/institution: Stringent application of existing laws. extent of emissions reduction, Term: Two to five years. obtained through a strict enforcement Target groups: Traffic authorities, vehicle owners and police. of the regulation, is about 1,000 tons (15 percent reduction of traffic- exhaust emissions). A summary of measures for abatement of excessively polluting vehicles is given in Table 4.3. Improving diesel quality Diesel's ignition and combustion properties are important parameters for explaining PMio emission from diesel engines (Hutcheson and van Paassen, 1990, Tharby et al., 1992). These properties include: volatility,4 viscosity,5 and cetane number. In Jakarta a minimum cetane number of 45 is specified for diesel fuel. In the United States, Western Europe, and Japan the corresponding number varies from 48 to 50. Diesel quality is also determined by the presence of detergents and dispersants in diesel fuels. These additives keep injection systems clean and have a discernible impact on efficiency (Parkes, 1988). Effectiveness. An improvement in the properties of diesel fuel, as expressed by a higher cetane number, and the addition of detergents results in a 10 percent reduction in PM1O emission or the equivalent of about 230 tons (1990 data). Reducing the sulfur content leads to a proportional decline in SO2 emission. PM1O emission also decreases because a part of the particulates comes from sulfur in the fuel. Costs. The cost of improving diesel fuel, especially improving the cetane number, is determined by the oil-product market, the refinery structure (capacity for producing light fuels, visbreaking, hydrotreating etc.), and government involvement in the national market. The latter finally determines the price of fuels at the pump. 4 Volatility is the ease with which a product begins to vaporize. Volatile substances have relatively high vapor pressures; therefore, they boil at relatively low temperatures. 5 Viscosity is the property of a fluid which determines its rate of flow. As a fluid's temperature increases, its viscosity decreases and it flows more readily. 6 The physico-chemical properties of diesel fuel, as expressed in the cetane number, influence the magnitude of TSP emissions of diesel powered vehicles. The relationship between these properties (such as volatility, viscosity) and the production of TSP in a diesel motor is not straightforward; the characteristics of the diesel motor, its load and its injection timing plan are other important parameters complicating the picture. URBAIR-Jakarta 47 The cost of reducing the sulfur content of diesel stems from the requirement for extensive desulfurization at the refinery. The cost of reducing sulfur from 0.7 percent to 0.2 percent is Rp20 per liter. When combusted, the sulfur in diesel fuel forms corrosive sulfuric acid. Therefore, lowering the sulfur content leads to a financial benefit, as there is a parallel reduction in the cost of vehicle maintenance and repair. Policy instruments and target groups. Recommentations to improve the quality of diesel fuel affect the energy policy of Indonesia and thus both authorities dealing with energy and fuel standards Table 4.4: Improving dieselfuel qualiky would have to be involved. Effectiveness: .230 tons PM1o (1990). Costs: Low. Term. The required adjustment of Benefits: Reduced mortality, 41; reduced RSD, 1 million; refineries, such as extension of avoided health costs, Rp5.9 billion; visbreaking capacity, would take reduction of S02 emission. abournstrumentsfinstution: Energy authorities. about 3-5 years. A summary for Term: Three-five years. abatement measures for improving Target groups: Petroleum industry. diesel fuel quality is in Table 4.4. Introduction of low-smoke lubricating oilfor two-stroke, mixed-lubrication engines Jakarta traffic has a large share of motorcycles and tricycles (locally known as Bajajs) equipped with two-stroke mixed lubrication engines. Exhaust from these vehicles causes about one-third (2,700 tons) of the PMIo emission. A substantial fraction of the particles emitted is in the form of droplets of unburned lubrication oil. According to Shell (private communication, 1993), the lubricating oil used in most South-Asian countries is cheap and has poor combustion properties. Effectiveness. It is assumed that the use of a better lubrication oil would cut the emissions in half (1,350 tons reduction). Costs. The introduction of these oils is estimated to double the costs of Table 4.5: Introduction of low-smoke lubricating oil. The annual consumption lubricating oil of these oils is estimated at 2,000-5,000 Effectiveness: 1,350 tons PM10 (1990). tons.7 Low-smoke lubricating oil may Costs: Rp2-10 billion. cost as much as Rp2-10 billion per year. Benefits: Reduced mortality, 220; reduced RSD, 5 million; Policy instruments and target groups. An avoided health costs ,Rp32 billion. economic instrument mnight be preferred. Instruments/institution: Regulations. economic nstrumen might bepreferre. * Term: Two years. A summary of this abatement measure is Target groups: Petroleum industry. given in Table 4.5. 7 Mileage of motorcycles and tricycles (Bajajs) is estimated at 5.3 billion km. At an average fuel efficiency of 0.02 liter/km, and an average content of 2-5 percent, total annual consumption of lubrication oil ranges from 2,000-5,000 tons. 48 Abatement Measures: Effectiveness and Costs Fuel switching in the transportation sector Switching to gaseous fuels such as Liquid Petroleum Gas (LPG) and Condensed Natural Gas (CNG) is another way of reducing PM1o emission. In areas where supply of LPG is abundant, it is widely used; fuel taxes favor its use. The use of LPG and CNG requires adapting the engine and its controls. This is economically feasible only when LPG and CNG cost less than gasoline or diesel. LPG can be used as a clean alternative to both gasoline and diesel. PMIo emission from LPG is very low. Currently, the use of LPG as an automotive fuel is prohibited in Indonesia (P.T. Mojopahit, 1991). This prohibition could be reconsidered. CNG use has been promoted for vehicles other than motorcycles or tricycles (Bajaj). Although it was introduced as an alternative fuel for taxicabs (Blue Bird), it has not been widely accepted. (P.T. Mojopahit, 1991). The investments for engine modification could be paid off within 1-1.5 year. A practical problem with CNG use is the loss of luggage space due to large fuel tank and a reduction in motor power. Effectiveness. CNG is used as substitute fuel in four-stroke gasoline engines. It is very T'able 4.6: Introduction of CNG to replace 50 percent of effective in reducing PMIo gasoline consumption (1990 situation), passenger cars emission (90 percent reduction). Effectiveness: 650 tons. If all gasoline cars had been Costs: Costs for vehicle owner depend on the price differential between gasoline and CNG (natural gas is cheaper). modified for the use of CNG, Benefits: Reduced Mortality, 98; emissions would have been 1,300 reduced RSD, 2 million; tons less in 1990 (about 3 percent avoided health costs, Rpl4,2 billion. of the total emissions). Table 4.6 Trade-off: Increase of emission of methane (greenhouse gas), the gives the estimated benefits of main constituent of natural gas. CNG use. Instruments/institution: Regulations and incentives. Term: Two-five years. Target groups Energy authorities. Costs. Investment in a taxi with a CNG tank and the modification of fuel-system in 1991 was estimated at Rpl.5 million. Given the fuel prices (gasoline versus CNG) in 1990-1991, costs were negative for taxi owners. Policy instruments and target groups. The use of CNG for automotive purposes, is an objective of the Indonesian government (Decree of Research and Technology Minister No. 887/M/BPPT/1986). Adoption of clean vehicle emissions standards Many countries have adopted standards for permissible emissions from vehicles. These standards require vehicles with four-stroke gasoline engines to be equipped with exhaust gas control devices based on the use of three-way catalysts (closed-loop systems). A few countries, including Austria URBAIR-Jakarta 49 and Taiwan, have also set standards for motorcycle emissions, requiring that two-stroke engine- powered vehicles be equipped with open-loop catalysts. Such catalysts control VOCs, PM1O, and CO emissions, but not NO,. The catalyst technology uses unleaded gasoline, the sulfur content of which should be less than 500 ppm. Therefore, introducing such standards requires the infrastructure for producing and distributing unleaded gasoline. Diesel-powered vehicles are also subject to regulations in Jakarta. The emission requirements are met by adjusting the motor design and management plan. Tailpipe emission treatment may also be used. Existing buses can be retrofitted with abatement equipment. If the latter method is to be used, the diesel must be of higher quality than is currently used (sulfur content below 0.02 percent). Such a standard is now being introduced in some parts of the world. Effectiveness: Closed-loop catalytic treatment of exhaust gases in gasoline engine vehicles (three- way catalysts) reduces exhaust emissions of NO,, CO, and VOC by about 85 percent. Because unleaded gasoline is required, lead emission is eliminated. Open-loop catalytic treatment of exhaust gases in two-stroke motorcycles reduces CO, VOC and PMIo (oil mist) emissions. There is 90 percent reduction in PMIo, otherwise the major source of emissions from two-stroke engines. Alternatively, using well-designed and maintained four-stroke engines leads to similar reduction in PM1O emission. Unleaded gasoline is a prerequisite for the use of catalytic devices for treating exhaust gases. Removing lead from gasoline changes its ignition properties; gasoline has to be reformulated to maintain ignition. This can be done by increasing the content of aromatics in gasoline, or by adding oxygenated compounds such as MTBE (methyl-tertiary-butyl-ether). Aromatics, however, include benzene, a carcinogenic compound. This may result in an environmental hazard, both from benzene exposure due to evaporation of gasoline (during production, storage and handling), and from an increase in the benzene content in exhaust gases (Tims et al., 1981, Tims, 1983). A limit on the benzene content of gasoline may be necessary. A decision on the specification of this limit would be based on current air quality data. Experience in other countries suggests that this issue can be resolved. Catalytic devices are effective in destroying benzene in exhaust gases. This all leads to the expectation that the net result is small-decrease of benzene emission from "clean" cars and (possible) increase of the exhaust emissions of dirty cars using unleaded gasoline. Unleaded gasoline with a high RON-number9 is usually produced by adding MTBE, the preferred lead substitute. MTBE must be imported into Indonesia. Costs. Due to methodological difficulties, it is not possible to calculate the total costs of introducing these standards in Jakarta. However, costs can be estimated on a vehicle-by-vehicle basis. 8 Aromatics are groups of hydrocarbons of which benzene is the parent. They are called "aromatics" because many of their derivatives have sweet odors. These hydrocarbons are of a relatively high specific gravity and possess good solvent properties. Certain aromatics have valuable anti-knock (octane) characteristics. Typical aromatics are benzene, toulene, xylene. The octane number of gasoline is a measure of its anti-knock value. The higher the octane, the higher is the anti-knock value of gasoline. 50 Abatement Measures: Effectiveness and Costs The cost of closed-loop catalytic treatments of exhaust gases stems from the increased purchasing cost of vehicles. In the United States, this increase averages US$400, ranging from US$300 to US$500 (Wang et al., 1993). While catalytic devices have a minor adverse effect on fuel economy, the associated costs are compensated by an increase in the lifetime of replacement parts such as the exhaust system. The cost of open-loop catalytic treatment of exhaust gases is related to increased equipment costs and decreased fuel costs due to improved engine operation. Taiwan has adopted standards requiring the use of open-loop catalytic devices. The increased cost of US$60-80 is offset by fuel savings (Binnie & Partners, 1992). Total annual costs are estimated at US$75 per vehicle (depreciation plus increased fuel costs). It is assumed that the cost for two-stroke engines or motorcycles is similar to the cost for four-stroke engines. Other costs include higher price of unleaded gasoline due to increased production cost and modifying pump nozzles. A very rough estimate of the cost is Rp200,000 annually per car (RpO10,000 for the depreciation of the control system and RplOO,000 in increased fuel costs, depending on possible subsidies/levies on gasoline). A summary of measures for adoption of clean vehicle standards is given in Table 4.7, and for motorcycles and tricycles in Table 4.8. Policy instruments and target groups. The following groups are involved in the introduction of "clean" vehicles: - firms that import vehicles; * car and motorcycle industry; * garages (must acquire the skills for maintenance of clean vehicles); D petroleum industry and gasoline retailers (introduction of clean cars requires the availability of unleaded gasoline); and vehicle owners (have to pay the price). Termn. In practice, standards can be set only for new cars and motorcycles as it is too expensive to equip existing vehicles with the necessary devices. Practically all vehicles currently sold in the world market are designed to be equipped with catalytic control systems. The effect of these standards will be shown gradually, reflecting the rate of replacement of existing vehicles. URBAIR-Jakarta 51 Table 4.7: Adoption of clean vehicle standards. Gasoline passenger cars and vans Effectiveness: 80% effectiveness per gasoline vehicle (for 1990, 900 tons). Costs: Rp200,000 (including costs of unleaded fuel) - order of magnitude! In total Rp18 billion. Benefits Reduced mortality, 147; reduced RSD, 3 million; avoided health costs, Rp2l billion (hypothetical situation in 1990); reduction of emissions of CO, NOx and VOC; the main justification for the introduction of these systems in other countries. Instruments/institution: Term: Two-five years; the result of such measures becomes clear with the renewal of the car fleet. Target groups: Petroleum industry makes unleaded fuel available, vehicle importers, vehicle manufacturers. Table 4.8: Adoption of clean vehicle standards for motorcycles and Bajajs (two-stroke engines) either requiring catalytic converters or four-stroke engines Effectiveness: 80% effectiveness per vehicle (in 1990, 2000 tons). Costs: Rpl 70,000 (including costs of unleaded fuel); total Rp67 billion. Benefits: Reduced mortality, >325; reduced RSD, >8 million; avoided health costs, Rp47 billion (hypothetical situation in 1990); reduction of emissions of CO, NOx and VOC; the main justification of introduction of these systems in other countries. Instrumentsfinstitution: Regulations. Term: Two-five years; the result of such measures becomes clear with the renewal of the fleet. Target groups: Petroleum industry makes unleaded fuel available, vehicle importers, vehicle manufacturers. Improvements in abatement, and other propulsion techniques The United States and European Union are considering the further tightening of standards. Methods to accomplish this include: * improving current abatement techniques; * improving inspection and maintenance, as small numbers of maladjusted/worn-out cars cause disproportionately large emissions; and * enforcing tie use of "zero-pollution" vehicles, i.e. electric vehicles in downtown areas. Although diesel engines emit less CO2 they are still a bottleneck in decreasing automotive air pollution because exhaust gas treatment similar to that for gasoline cars is not available. Addressing resuspension emissions Although resuspension is a high priority issue in Jakarta, there is lack of quantitative information about city-appropriate abatement measures. Future analyses should give priority to measures dealing with resuspension. In general, all methods for reducing entrainment should be evaluated and applied. Controlling resuspension of road dust may be the most cost effective way of reducing TSP exposure. 52 Abatement Measures: Effectiveness and Costs Improving traffic management Traffic management includes a variety of measures including: traffic control by police or traffic lights; one-way streets; new roads, and road-pricing systems. One of the main aims of traffic management is to solve congestion problems. Curbside traffic management may improve air quality'0, but it may also increase air pollution because it usually results in the increased use of the transport system. In terms of exposure, traffic management leads to improvement in downtown air quality and reduction in road exposure. In terms of total exposure, however, the net result may be small. Improved traffic management has other environmental benefits such as less noise and congestion. Although more detailed analysis is needed, traffic management appears to e a cost-effective policy. Constructing and improving mass-transit systems Mass-transit systems, such as light-rail transport, may solve environmental problems due to traffic and the need to increase transport capacity. Building such systems is a long-term process requiring large investments. Assessing the costs and effectiveness of measures to improve Jakarta's public transport system, including the construction of mass-transit systems, involves: - describing a future system appropriate for Jakarta; * assessing the performance of such system (passenger-kilometers); • estimating construction costs; D describing the baseline (future situation without such a system); * estimating avoided emissions; - assessing non-environmental benefits; and - designing a scheme to identify costs and benefits addressing environmental concerns. The costs of constructing mass-transit systems are high. Projects cannot be justified from an air-pollution point of view alone. However, mass-transit systems have a wide variety of other benefits, including reduction in traffic congestion. CONTROLLING POLLUTION FROM LARGE POINT SOURCES Cleanerfuels in existing plants. Power plants are not a large cause of air quality problems in Jakarta. The use of cleaner fuel such as low sulfur oil, cleaner coal, or natural gas may be contemplated. The benefits of such a switch would be a reduction in SO2 and CO2. Fuel combustion other than in power production. PM10 emission also results from the combustion of fuel oil in small industries (source category "domestic"). This emission is estimated at 1,700 tons (+1,620 tons from distillate fuel). The damage associated with this emission is low (mortality 13 RSD below one million, health cost below Rp2 billion). 1o Accelerating vehicles, a prominent feature of congested traffic, emit disproportionately large amounts of pollutants. URBAIR-Jakarta 53 INDUSTRIAL PROCESSES (NON-COMBUSTION SOURCES) Lack of data on process emissions estimated at 14,000 tons per year prevents addressing appropriate abatement measures. Rough estimates based on data from large factories producing steel ingots and billets indicate that TSP emission may be reduced by 4,000 tons/year at an investment cost of 10 million dollars (COWI/World Bank, 1992). OPEN BURNING AND CONSTRUCTION Refuse burning results in an estimated 7,000 tons of PMIo. A concrete proposal to address this emission requires more information on the characteristics of the source. PM1o emission due to construction is estimated at 10,000 tons, with demolition activities being the main source. There are various ways of controlling this emission, including screens alongside demolition sites, the use of chutes to remove rubble, etc. However, emission details are lacking, and it is not possible to develop a proposal for abatement measures. CONCLUSIONS There are a number of measures that are appropriate for improving the air quality in Jakarta. An important issue is estimated benefits which translates into reduced health costs and reduced damage costs. Information on the costs and benefits of each measure is needed in order to establish priorities. Traffic emissions are a major cause of air pollution. Measures that stand out from a cost- benefit point of view are: - introduction of unleaded gasoline; * introduction of low-smoke lubricating oil; and * (further) development of the use of natural gas both for automotive and stationary use. A similar listing of measures addressing other pollution sources was not possible due to lack of data. This is unfortunate because other sources appear to be more important than traffic, including: * resuspension of particles, mainly from traffic and roads; * industrial process emissions; and * open refuse or biomass burning. 5. ACTION PLAN The proposed action plan is based on the cost-benefit analysis of various measures that reduce air pollution and resulting damages. This plan is based on available data, the shortcomings of which have been identified throughout this study. Improving the database is necessary in order to extend the action plan to include additional measures. The "actions" fall into two categories: 1. Technical and other measures that will reduce the exposure and damage; and 2. Improving the database, and the regulatory and institutional basis for establishing an operative AQMS in Jakarta. This includes raising public awareness and promoting public and private sector cooperation. Examnples of successful initiatives include the Adopt-a-Street approach in which the private sector becomes responsible for socially responsible environmental management and awareness raising. Environmental education and outreach via television and newspaper are equally important. ACTIONS TO IMPROVE JAKARTA'S AIR QUALITY AND ITS MANAGEMENT Actions to improve air quality Actions and measures have been proposed by the Jakarta URBAIR working groups, through other World Bank studies, and by the URBAIR consultants. Proposed actions and measures are categorized as (1) improved fuel quality, (2) technology improvements, (3) fuel switching, (4) traffic management, and (5) transport demand management. A proposed action plan of measures which can be introduced in the short term is given in Table 5.1. The calculated benefits of many of the measures are substantial. For some of the measures, such as low-smoke lubricating oil and improving diesel quality, the monetary benefits are higher than the estimated costs. Lowering the lead content in gasoline is an important measure that has already been initiated through legislation. Lead-free gasoline is a prerequisite for clean vehicle standards and is not listed as a separate measure. Success of these measures requires enforcement. It is important to ensure that technical improvements and adjustments such as repair shop capacity, capability for efficient adjustment of engines, and availability of reasonably priced spare parts are ensured. The actions incorporate the following measures. Addressing excessively polluting vehicles: * strict enforcement of smoke opacity regulation. 55 56 Action Plan Table 5.1: Action plan of abatement measures Benefits Time frame Abatement measure Avoided Avoided health damage Cost of measure Introduction Effect of emissions, of measure measure tons of PM,, per year Vehicles Low-lead and -- Rp300 billion Rp40-6011iter, total Immediate 2-5 years unleaded fuel 340 deaths, loss of lQ Rp5O billion points in children Inspection/ 1,300 Rp3l billion Rp67 billion Immediate 2-5 years maintenance 212 deaths, 5 million RSD Address excessively 1,000 Rp24 billion Low Immediate 2 years polluting vehicles 163 deaths, 4 million RSD Low-smoke 1,350 Rp32 billion Rp2-1 0 billion Immediate 2 years lubricating oil, 2- 220 deaths, 5 million RSD stroke engines Improving diesel 230 Rp6 billion Low Immediate 2-5 years quality 41 deaths, 1 million RSD CNG to replace 50% 650 Rp14 billion Unknown Short -5 years of gasoline 98 deaths, 2 million RSD consumption Clean vehicle 2,900 Rp68 billion Rp85 billion Immediate 5-15 years standards 500 deaths (Passenger cars and 12 million RSD MC/Bajaj) * routine maintenance/adjustment of engines. Improving diesel quality: * import of quality low-sulfur diesel (0.2 percent); * modifications in Indonesian refineries; or * taxes/subsidies to differentiate fuel price according to fuel quality. Inspection/Maintenance: * annual (or bi-annual) inspection; and * establishment of inspection and maintenance stations (government or private). Clean vehicle emissions standard: * state-of-the-art vehicle emissions standard for gasoline cars, diesel vehicles and motorcycles; and * availability of lead-free gasoline at a lower price than leaded gasoline. Awareness raising: * public participation in AQMS process to successfully implement environmental education; * private sector participation in innovative schemes; and * information dissemination through all media. URBAIR-Jakarta 57 Table 5.2 lists abatement measures for which cost-benefit analysis has not been performed. These measures could also be introduced in the short term, and would benefit air quality. Table 5.2: Additional measures for short- to medium-term introduction Time frame Abatement measureiaction Introduction of Effect of measure measure Vehicles Address dilution and adulteration of fuel Short-term Short-term Restrict life time of public UVs and buses Short-term Medium-term Traffic management Improve capacity of existing road network - improve surface Short-term Medium-term - remove obstacles - improve traffic signals Extend/develop road network: Improve/eliminate Short-/medium-term Medium-term bottlenecks Transport demand management Improve existing bus system - improve time schedules Short-term Medium-term - improve junctionststations - make integrated plan Develop parking policy - restrictions in central area Short-term Short-term - parking near mass transit terminals Short-term - car-pooling Short-term Actions to improve the AQMS A successful AQMS Table 5.3: Actons to impove air qualy assessment in Jakarta requires putting into action Air Quality Monitoring . Improve the ambient air, monitoring system, the best possible air quality * Upgrade laboratory facilities and man-power capacities, assessment, damage and * Establish a quality control system, cost assessment, . Establish database, suitable for providing Air Quality information to the public/control aaencies/law makers. institutional and regulatory ...--- ---- ........................... .... --- .... ........... insttutona andrel Emissions * Produce inventory of industral emissions, framework, and awareness . Develop integrated, comprehensive emissions inventory building among the public procedure, and policymakers. A . Stud resuspension from roads. ......................................................... :.. .........I..................................................................................... summary of actions to Population exposure * Establish appropriate dispersion modeling tools for improve the AQMS in control strategy in Jakarta. Jakarta are listed in Table 5.3. A COMPREHENSIVE LIST OF PROPOSED MEASURES AND ACTIONS Table 5.4 presents the proposed action plan with measures to improve the air quality in Jakarta. 00 Table 5.4: Categorized action list to improve the air quality in Jakarta S: <2 years, M: 2-5 years, L: 5-10 years, VL: >1Oyears WHAT HOW WHEN WHO EFFECTS COST FEASIBILITY REMARKS CATEGORY: Improved Fuel Quality Address dilution and adulteration of Improved enforcement S/M DOE 10% reduc- fuel existing law tion TSP Decrease lead-level in leaded gasoline Mandatory regulation S/M DOE, Petrol industry Market unleaded gasoline. Evaluate Voluntary-use tax system S/M DOE, Petrol 100% reduc- additives. industry tion of lead Phase-out of leaded gasoline. Time Mandatory regulation M/L schedule. Upgrade diesel-fuel quality (volatility, Alter fuel quality S/M DOE, Petrol 10% reduc- sulfur) standards industry tion TSP Decrease maximum allowable S Regulation, phased S/M DOE Requires content in fuel oil refinery restructure CATEGORY: Vehicles (Technology Improvement) 1. State-of-the-art emission control for Extend present S/M-L new cars, gasoline regulations, set time schedule 2. State-of-the-art emission control for Extend present S/M-L new motorcycles regulations, set time schedule 3. State-of-the-art emission control for Extend present S/M-L new light duty diesel vehicles (cars) regulations set time schedule 4.State-of-the-art emission control for Extend present S/M-L heavy duty diesel vehicles (UV, buses, regulations set time trucks) schedule 5. Vehicles Address highly polluting vehicles: Table 5.4: Categorized action list to improve the air quality in Jakarta S: <2years, M: 2-$years, L: 5-10years, VL: >10years WHAT HOW WHEN WHO EFFECTS COST FEASIBILITY REMARKS a. Control emissions from diesel UV, Enforce existing S/S trucks regulation l/M system. The use of diesel particle oxidizers/trups should be evaluated as suggested by Dr. Mike Ruby. b. Restrict life of public utility -- S/M vehicles/engines and buses c. Control emission from gasoline vehicles INDUSTRIAL SOURCES Licensing (emission Use of emission control equipment reg's)/ Charges on Process modifications/improvement emissions/ Promote good environmental practices CATEGORY: Fuel Switch 1. LPG for transport (buses, PUV) Study CNG utilization for S CNG for gasoline transport; 2. Natural Gas in industry Study possibilities S (resources) 0y Table 5.4: Categorized action list to improve the air quality in Jakarta S. <2years, M. 2-5years, L: 5-10years, VL: >10years WHAT HOW WHEN WHO EFFECTS COST FEASIBILITY REMARKS CATEGORY: Traffic management Improve traffic flow a. Improve existing road network Place responsibility, S/S b. Extend/develop road network enforce S/M - Analysis of the situation (bottlenecks, etc.) c. Improve/co-ordinate traffic signal - Support responsible systems agencies d. Segregate mass transport from other modes. e. Improve facilities for non-motorized traffic Develop network of truck terminals, as part of a scheme for efficient transport of goods. CATEGORY:. Transport Demand Management Expansion of bus system. Advocate & Support Introduction of light-rail system Survey present mass-transit situation, and develop comprehensive/ integrated plan for mass transit in MM, based on existing components: - improve time schedules, coordination - improve junctions/stations, especially where several modes meet. Survey new concepts for person transport (APM, guideway bus system, etc.) and evaluate its possible use in Jakarta. Table 5.4: Categorized action list to improve the air quality in Jakarta S: <2 years, M. 2-5 years, L: 5-0years, VIL: >lvears WHAT HOW WHEN WHO EFFECTS COST FEASIBILITY REMARKS Promote non-motorized traffic (NMT) incl. improve/construct facilities, such as lanes and roads for NMT Land use planning to reduce transport demand Use parking policy to influence traffic mode mix, e.g. - parking restrictions in central areas, - parking facilities near mass transit terminals, - carpool guidance system. CATEGORY:. InventoryinglDispersion Modeling Improve emission inventory for DKI Jakarta a. Produce inventory of Industrial- S's emissions (location, pro- process, emissions, stack data) b. Improve inventory of road and traffic S/S data c. Improve inventory of domestic S/S emissions d. Study resuspension S/M - from roads, - from other surfaces Develop an integrated and S-M comprehensive emission inventory procedure, incl. emission factor review, update and QA procedures. Assess current modeling tools/methods, and establish appropriate models for control strategy in DKI Jakarta. Table 5.4: Categorized action list to improve the air quality in Jakarta. S: <2years, M: 2-Syears, L: 5-10years, VL: >10years WHAT HOW WHEN WHO EFFECTS COST FEASIBILITY REMARKS CATEGORY:. Air Quality Monitoring Design and set up S modified/improved/extended monitoring system Design and establish Quality S Control/Quality Assurance System - evaluation of sites; number and location - selection of methods/parameters/ monitors/frequency of operation. Establish data base of all DKI Jakarta data regarding - air quality - meteorology (dispersion) CATEGORY: . Institutional and regulatory framework CATEGORY: Awareness raising Promote environmental education, on- adopt innovative schemes that involve going public/private sector participation; involve media in dissemination of air pollution data and awareness issues. CATEGORY: Further studies Study resuspension from roads 6. INSTITUTIONS, FUNCTIONS, AND POLICY PLANS INSTITUTIONS Central control The State Ministry of Environment is the main central body responsible for environmental management and regulation. Environmental legislation began with Decree 02/MENKLH/I/1988, issuing pollution standards for air and water. One Assistant-Minister coordinates mobile source air pollution management with the Ministries of Industry and Health. Another Assistant-Minister coordinates industrial air pollution control together with the Ministries of Industry and the Interior. BAPEDAL was established in 1990 as a central control agency for environment in Indonesia. BAPEDAL's organizational structure is shown in Figure 6.1. The World Bank and other consultants have been involved in the BAPEDAL Development Plan to be implemented over six years. Other organizations have proposed the creation of an Environmental Management Centre for research and training, and a Reference Laboratory as part of BAPEDAL. Bureau of Environment The Bureau of Environment (BLH) comes under the organizational umbrella of the Assistant of the Secretary for Social Welfare at the Secretariat of the Province. The structure of BLH is complicated and would benefit from simplification. Its mandate includes the following: * developing implementation and technical guidelines for industrial emissions; * coordinating the formulation of implementation guidelines of motor vehicle emissions standards; * public awareness programs focusing on clean air, for example, encouraging people not to use their cars, especially on holidays; * coordinating an implementation study for staggering working hours and work-days; * coordinating assessment and program formulation on the age limit for motor vehicles; and * air quality monitoring program and utilization plan for mobile monitoring equipment. 63 Figure 6.1: Organization structure of central BAPEDAL (1990) Ead Local and Public Relation Administration | Local Affairs Personeneit ll Public Relation [ < }~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~eeec LabFmante | Deputy for Envronnental Depytt for PollutLn Controo Development _~~~~~~~~M-:, . I Directorate for Wabter Directorate for _Directo)rate for .DMrectorate for and Land Pollution Maane and Air Directorate for Development Control Direorate for Development of _ Control _ Pollution Control _ Hazardous Waste _ and Monitoring of EIA _ Technical Guidance RefeDaa rencessing Control~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~adDtaPoesn Small Scale ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~~~~~~~~~~Cos etra n Activities .impact ControlCai C | Development of Domestic Waste system l l 2 Info System andm| I ILAir Pollution &I G ItrcieSse I Developmentaiut of Control Managementro Enirnmeta Environmental Destruct. |Control of EIAQuality Development Evaluation Control | Costal L j~- Pollution ControlI II Small Scale Activities Impact Control| |Domestic Waste _ Control Management| | | $~~~~ource: BAPEDAL (I1993). URBAIR-Jakarta 65 Road Traffic and Transportation Department The Road Traffic and Transportation Department (DLLAJR) is in the Jakarta Provincial Government. It is responsible for the control of road traffic and transportation, including road worthiness of motor vehicles and their emissions. Its mandate includes: * coordinating the checking and enforcement of inspection requirements for motor vehicles with the local government and traffic police; * integrating the computer system on car registration and inspection; * assigning private car garages and mechanics to participate in car exhaust inspection and issue pollution-free certificates; and * leading an information campaign on the use of catalytic converters. KPPL KPPL is the regional implementation unit of urban and environmental research and development, directly responsible to the governor of DKI Jakarta. The administrative coordination structure of KPPL DKI Jakarta consists of: - Head of KPPL DKI Jakarta. * Administrative Division - Sub-division of Correspondence and Personnel, - Sub-division of Finance, - Sub-division of Equipment and Households. * Programming and Evaluation Division - Data and Information Section, - Program Formulation Section, - Program Evaluation Section. * Functional staff include research groups - Urban Ecology, - Environmental Management, - Urban and Environmental Socioeconomy and Socioculture, - Urban and Environment legislation, - Laboratory Analysis, - Librarian, - Computer group. KPPL shares some of the responsibilities for developments in Jakarta, especially on urban and environmental issues. Its responsibilities also include: * collecting data and information to formulate programs and evaluate their implementation; * assessing urban ecology, environmental management, socioeconomic, sociocultural and legal aspects of urban and environmental issues; * carrying out laboratory analysis, and * technical coordination of the regional government institutions that are involved in the integrated assessment of urban and environmental issues. 66 Institutions, Functions, and Policy Plans KPPL DKI Jakarta has four laboratories. The Physical and Chemical Laboratory analyzes river, ground, sea water, land and sludge, plant, vegetable, and fish samples. Water analysis includes parameters such as conductivity, turbidity, color, temperature, acidity/alkalinity, chloride, ammonia, nitrate, nitrite and total nitrogen, sulfate, sulfide, hydrogen sulfide, fluoride, hardness, suspended solids, total dissolved solids, chemical oxygen demand, biochemical oxygen demand, detergent, cyanide, iron, copper, lead, chromium, nickel, manganese, mercury, cadmium, calcium, magnesium, sodium, potassium, and caloric value. The Microbiology Laboratory analyzes microbiological parameters including, plankton, benthos, coli form, fecal coli, and tests by using bioassy. The Air and Sound Laboratory analyzes air quality, emissions, and sound/noise. Analysis of air includes testing for NO,, NO, SO2, dust, ozone, H2S, ammonia, hydrocarbons, CO, C02, Wind speed and direction, heavy metals in the dust, and rainfall. The Toxicology Laboratory performs analysis of organic chemicals, and pesticides, including hazardous materials. KPPL also conducts physical surveys such as the regular monitoring of river water, and ambient air quality. The results of KPPL surveys have been extensively used by the Regional Administration to establish environmental monitoring policies. Environmental support network The Ministry of Environment has developed the university-based Environmental Studies Centers (PSL). The primary objective of PSL is to increase the availability of environmental experts who can advise officials responsible for environmental planning and policy analysis. Another initiative is to encourage the development of environmental NGOs. Many of the larger NGOs belong to WALHI, the umbrella network of environmental NGOs, established in 1980. FUNCTIONS The MEIP analysis of key institutions (Bulkin, 1992) provides the overview of institutional functions and linkages in air management shown in Figure 6.2. BAPEDAL is not included yet in the matrix, nor in the matrices for water, waste, etc., indicating that the BAPEDAL is still in the development stage. The overview of central institutions responsible for air pollution management is based on Figure 6.3. Figure 6.2: Institutional linkages in managing air pollution according to management functions Cen tral government Management function KLH MOHA MOPW MOTA MOIA Policy * * * * Standard formulation Planning: a. Infrastructure b. Services . Pollution Control: a. Permitting * * * b. AMDAL * * * * c. Monitoring * * * _ d. Law enforcement * * * _Provincial government _ .. Management function KPPL AOH AOPW BAPPEDA GOV SEKWILDA BKLH AOID BKPMD DLLAJR Policy* **** Standard formulation * * * _ Planning: a. Infrastructure * * b. Services * * * * * Pollution control: a. Permitting * * * b. AMDAL * . * * * * c. Monitoring * * * * * * * * * * d. Law enforcement * * * Source: Bulkin (1992). Figure 6.3: Diagram of interagency linkages in air quality management 00 |KLH (ASMEN 11)l |KLH (ASMEN 111) +mJLJ L MOTA . ~MOHA MODMOiA| MOEC MO MP r~~~~~~~~~~~~aW GL . § a X L~ ~ ~~~ J L > - s Hq~~~~~~~~~~~~~~~ BKLH Unvrie 1~~~~~~~~~~~ L Source: Bulkin (1992). URBAIR-Jakarta 69 Monitoring Central government. Central Ministries of Health, Public Works and Transportation share the responsibilities of monitoring air pollution. Provincial government. Ten agencies are responsible for air pollution monitoring. BMG, not included in Figure 6.3 should also be on this list. Actual monitoring in Jakarta is done by JMB (GOV), BMG, and KPPL. The other agencies issue information from the monitoring to public, and to other agencies for the purposes of planning and enforcement. Permits Central government. The Ministries of Environment, Public Works, and Transportation are responsible for permitting and licensing air polluting activities. Provincial government. KPPL, and the Ministries of Public Works and Industry, the Provincial Investment Board, and the Agency of Traffic and Highway Transportation have permitting and licensing functions. AMDAL environmental impact assessment The Environmental Impact Assessment (EIA) process for new and existing polluting activities involves the Ministries of Environment, Health, Public Works, and Transportation at the central level; and the Ministry of Industry, Bureau for Population and Environment, Office of Urban and Environment Studies, Traffic and Highway Agency, and the Investment Coordinating Board at the provincial level. Law enforcement The Ministries of Environment, Health, Public Works and Transportation have functions regarding law enforcement at the central level. At the provincial level, the Municipal Government, the Ministry of Industry, and the Investment Control Board are responsible for law enforcement. Emissions standards The DLLAJR is responsible for vehicle emissions standards in Jakarta. Other institutions involved in the implementation of vehicle emissions include: * Provincial Planning Board of Jakarta (BAPEDAL), * Bureau of Environment (BBLH), * Urban and Environment Assessment Office (KPPL), 70 Institutions, Functions, and Policy Plans * Bureau of Economic Facilities Development (Bangsarekda), * Bureau of Law Enforcement (Ro Ketertiban), * Regional Investment Board (BKPMD), * Department of Health (DKK), * Department of Industry (Dinas Perindustrian), * Department of Public Works (DPU), * Department of City Planning (Dinas Tata Kota), * Bureau of Legal Affairs (Ro Hukum). Supervision of the emission parameters evaluation is coordinated by the Urban and Environment Assessment Office. The Bureau of Environment is responsible for coordinating the implementation evaluation. The Bureau of law evaluates regulation. EXISTING LAWS AND REGULATIONS ON AIR POLLUTION Air pollution legislation in Indonesia, and in Jakarta, has been described in detail in a report by LL:AJR Air Pollution Monitoring and Control Project performed by Institut Teknologi Bandung (Bachrun et al., 1991), by Kozak and Sudarmo (1992), and by Budirahardjo (1994). In these references, the national air pollution legislation is summarized as follows: * Law No. 4/1982 "The Basic Provisions for the Management of the Environment". This is the umbrella provision for all environmental regulations in Indonesia. Under this law, the KLH (State Ministry for Population and Environment) issued the Ministerial Decree KEP- 35/MENKLH/10/1993, which established national ambient air quality standards and emissions standards for stationary sources. The compounds listed in this decree are SO2, NO2, TSP, CO, 03, HC, Lead, H2S, and NH3 and smoke emission (opacity) from diesel vehicles. These standards act as guidelines for the provinces to accept or develop more stringent standards. * Government Regulation 29/1986, specifying the AMDAL process for central ministries to undertake Environmental Impact Analysis on existing and new projects. The AMDAL process is still developing, but is hampered by the lack of trained reviewers and qualified consultants. * Decree No. KM-8-1989 of the Minister for Communications addresses Vehicle emissions standards in the context of road worthiness. This decree limits CO and HC emissions from idling gasoline powered vehicles. * Draft Regulation of KLH has been promulgated as the Decision of the State Minister of Environment no. KEP-35/MENLH/10/1993 on Emissions standards for Motor vehicles (note from S. Hadiwinoto, 1994). * Draft Regulation "Government Regulation for the Control of Air Pollution". Drafted by KLH and an interdepartmental Air Quality Technical Committee. This regulation describes responsibilities for air quality monitoring and data collection, such as emissions inventories, and specifies BAPEDAL as the agency responsible for an air pollution control program. The Regulation also outlines a permit process, and sanctions. The Draft Regulation was expected to be promulgated before the end of 1992. * Regulations on tetraethyl lead contents in gasoline, under the Ministry of Mines and Energy. The lead content has been reduced from 2.5 ml per U.S. gallon in the mid 1980s to 1.5 ml per U.S. gallon (0.449 1) for all gasoline qualities. Production of lead-free gasoline has been discussed. URBAIR-Jakarta 71 * Act number 14 of 1992 oh Traffic and Land Transportation states that all motorized vehicles are subject to testing with respect to emissions and noise. * Decree KM 71 of 1993 of the Ministry of Transportation is on the periodical test of motorized vehicles. The responsibility for testing rests with the Provincial Government, and the tests are to be carried out by the Traffic and Transportation Service in the province, or delegated to the Traffic and Transportation Service at local government level. Regarding air pollution regulations in Jakarta, the above-mentioned references list the following: * Governor's Decree No. 382 Year 1977, on the obligation of companies and entities, engaged in industry within the territory of the Capital City of Jakarta to investigate their wastes to the PPMPL Laboratory or a Laboratory appointed by the authorities. * Governor's Decree No. 220 Year 1979, grants authority to enter industrial companies and entities within the territory of the Capital City of Jakarta for the purpose of inspection and investigation of industrial waste. * Governor's Decree No. 587/1988, issues ambient air quality standards. These are equivalent to the national standards. * The Decision of the Governor of DKI Jakarta No. 709 Year 1990, on the establishment of the coordination team for the enforcement of environmental regulation within the territory of DKI Jakarta. * The Decision of the Governor of DKI Jakarta No. 1117 Year 1990, on the appointment of the Centre for Research and Development of City and Environment (P4L) DKI Jakarta which has the authority to inspect, and to issue the result of laboratory analysis for the purpose of evidence in cases of violation of laws on the regulation on environment in the territory of the DKI Jakarta. * Governor's Decree No. 1222/1990, issues vehicle emissions standards, also equivalent to the national standards. DLLAJR is responsible for vehicle emission testing in Jakarta. * Governor's Decree No. 1236/1990 on the implementation of vehicle emission control. * Provincial Act No. 5/1984 on a Master Plan of Jakarta up to the year 2005, mentions zoning. Two experiments have so far been carried out. "Three in One" requires that cars, on specified roads, must transport at least three passengers. In a number of places a special bus lane was introduced. The results of the experiments appear to be positive. Blue Sky Program. The Ministry of Environment launched "Program Langit Biru" (Blue Sky Program) in 1991, to address air pollution problems. For stationary sources, the program gives priority to power plants, cement, paper and pulp, and steel industries. To control air pollution from mobile sources, BAPEDAL plans to control black smoke and switch to unleaded gasoline. The Clean Air Program (Prodasih), announced in 1991, is an effort to increase public awareness of air pollution, and to emphasize the enforcement of Decrees. Recent publications Publications describing the institutional environment/air pollution management and control in Indonesia and Jakarta include the following: * Bachrun, R.K., H. M. Samudro, M. Soedomo, and B. Tjasjono. 1991. "LLAJR Air Pollution Monitoring and Control." Institut Teknologi Bandung. 72 Institutions, Functions, and Policy Plans * Kozak, J.H. and R. P. Sudarmo. 1992. "An overview of air pollution in Indonesia." Environmental Management Development/KDH, Jakarta. * Bulkin, F. et al. 1992. "Analysis of key institutions affecting urban environmental quality in Jakarta Region." Institute of Research and Development of Social Sciences of the University of Indonesia in cooperation with MEIP-World Bank. * Budirahardjo. 1994. "Regulations and Institutions in Air Pollution." URBAIR report. SHORTCOMINGS Efficient management requires clear lines of authority and responsibilities. Many institutions in Jakarta have overlapping responsibilities for the environment. Institutional shortcomings include the lack of control and law enforcement, and shortage of well-trained personnel and qualified consultants. Selected reasons for inefficient control and monitoring are as follows: * functional relationships between agencies are unclear; * poor communication and cooperation between agencies; * enforcement agencies often do not refer to reports on pollution problems to take legal action; * the perception of policies and law enforcement is often not clearly stated; * socio-cultural obstacles, including the effects of the patrimorial relation of authority, which tends towards serving higher authority rather than the interests of society; and * obstacles in Government-Private Sector cooperation. REFERENCES Achmadi, U.F. 1994. "An Assessment of the Environmental Impact of Air Pollution." Report prepared for the URBAIR project. Faculty of Public Health, Univ. of Indonesia. Jakarta. BAPEDAL. 1994. "Third Jakotabek Urban Development Project (JUDP III). "Phase Im Report." Jakarta. Baker et al. 1992. "Vehicular Emission Control Planning in Metro Manila." Asian Development Bank (T.A. No. 1414-PHI). Manila. Bachrun, R.K., Samudro, H.M., Soedomo, M. and Tjasjono, B. 1991. "LLAJR Air Pollution Monitoring and Control." Institut Teknologi Bandung. Indonesia. Binnie & Partners Consulting Engineers. 1992. "Modernization of Environmental Monitoring Facilities & Capabilities in Response to Philippines' Energy Development Project." Interim report to the EMB. Jakarta. Bosch, J. 1991. "Air quality assessment in Medan." Extract from Medan urban transportation study. Final Report. The World Bank. Washington DC. BPPT/KFA. 1992. "Environmental Impacts of Energy Strategies for Indonesia: Emission Coefficients and Spatial Distribution Sources." BPPT/Forschungzentrum Julich. Jakarta/Bonn. Budirahardjo. 1994. "Regulations and Institutions in Air Pollution." URBAIR report. Jakarta Bulkin, F. et al. 1992. "Analysis of Key Institutions Affecting Urban Environmental Quality in Jakarta Region." LLPIS, FISIPUIVMEIP-World Bank. Jakarta. Calkins, R., A. Liebenthal, S. Gosh, D. Hanna, and D. Wheeler. 1994. "Indonesia Environment and Development: Challenges for the Future." (Report No. 12083-IND). World Bank. Washington, DC. Clairbom, C. et al. 1995. "Evaluation of PM10-emission Rates from Paved and Unpaved Roads Using Tracer Techniques." Atmos. Environ., 29, 1075-1089. COWIconsult/World Bank. 1992. Industrial Efficiency and Pollution Abatement (IEPA) project. List of 100 industries which may qualify for assistance. Washington, DC. Dichanov, Y. 1994. "Sensitivity of PPP-based income estimates to choice of aggregation procedures." World Bank, Washington, DC. DMV Consultants. 1993a. "Third Jabotabek Urban Development Project (JUDP III): Small-scale Industries Waste Reduction in Jakarta." DMV Consultants B.V. (078). Jakarta. DMV Consultants. 1993b. "Third Jabotabek Urban Development Project (JUDP III): Joint Waste Water Treatment For Industrial Estates." DMV Consultants B.V. (079). Jakarta. Gram, F. and T. B0hler. 1993. "User's Guide for the KILDER Dispersion Modeling System." (NILU TR 5/92). Lillestr0m, Norway. Environmental Management Center-EMC. 1994. "Annual Report on Air Quality Monitoring and Studies." Serpong. 73 74 References Haugsbakk, I. and S. Larssen, S. 1985. "Measurements of Particle, Soot and Lead Emission from Gasoline-Powered Light Duty Vehicles with Various Test Cycles." (NILU OR 3/85) (in Norwegian). Lillestrom, Norway. Hutcheson, R. and C. van Paassen. 1990. "Diesel Fuel Quality into the Next Century." Selected Papers. Shell Public Affairs. London. Jakarta Statistical Office. 1991. "Jakarta in figures." Kozak, J.K. and R. P. Sudarmo, R.P. 1992. "An Overview of Air Pollution in Indonesia." EMDIVKDH. Jakarta. Lave, L.B. and E. S. Seskin. 1977. Air Pollution and Human Health. Baltimore/London:John Hopkins University Press. Mehta, K.H. et al. 1993. Toward Improved Environmental Policies and Management. Philippines Environmental sector study. World Bank (Report No. 11852-PH).Washington. Mitchell, T. 1991. "Program for Development of Air Control Activities of BAPEDAL." Redecon Consultants. Jakarta. Mojopahit Konsultana, P.T. 1991. "Assessment of Transportation Growth in Asia and its Effect on Energy Usage, Environment and Traffic Congestion." Case study. Surabaya. Ostro, Bart. 1994. "Estimating Health Effects of Air Pollution: A Methodology with Application to Jakarta." Policy Research Working Paper 1301. The World Bank. Washington, DC. Parkes, D. (1988) Matching supply and demand for transportation in the Pacific Rim countries post 1990. Selected papers. London, Shell. Shah, Jitendra, Tanvi Nagpal, and Carter Brandon (eds.) 1997. Urban Air Quality Management Strategy in Asia: Guidebook. The World Bank. Washington, D.C. Shin, E., R. Gregory, M. Hufschmidt, Y.-S. Lee, J.E. Nickum, and C. Umetsu. 1992. "Economic Valuation of Urban Environmental Problems." World Bank. Washington D.C Soedomo, M. 1993. Collection of data for the URBAIR study in Jakarta. Institut Teknologi Bandung. Tharby, R.D., W. Vandenhengel, and S. Panich. 1992. "Transportation Emissions and Fuel Quality Specification for Thailand." Monenco Consultants. Oakville, Canada. Tims, J.M. 1983. "Benzene Emissions from Passenger Cars." (Concawe report 12/83). Brussels. Tims, J.W. et al. 1981. "Exposure to Atmospheric Benzene Vapor Associated with Motor Gasoline." (Concawe report 2/81). Brussels. Turner et al. 1993. "Cost and Emissions Benefits of Selected Air Pollution Control Measures for Santiago, Chile." Report to the World Bank., Engine, Fuel, and Emissions Engineering, Inc. Sacramento, CA. United States Environmental Protection Agency (USEPA). 1986. "Fuel Oil Combustion." In: Compilation of Air Pollutant Emission Factors 4th edition. Research Triangle Park, NC. Wang, Q., C. Kling, and D. Sperling. 1993. "Light-duty Vehicle Exhaust Emission Control Cost Estimates Using a Part-pricing Approach." Journal of the Air Waste Management Association. 43, 1461-1471. Weaver, C.S. and P. E. Lit-Mian Chan. 1993. "Motorcycle Emission Standards and Emission Control Technology." Report to the World Bank and The Thai Government. Engine, Fuel, and Emissions Engineering, Inc. Sacramento, CA. World Bank. 1993. Indonesia: Energy and the Environment.Plan of Action for Pollution Control. East Asia and Pacific Region (Report No.1 181 -IND). World Bank. Washington, DC. World Health Organization/United Nations Environment Programme. 1992. Urban Air Pollution in Megacities of the World. Cambridge, MA:Blackwell Publishers. APPENDIX 1: AIR QUALITY STATUS, JAKARTA DESCRIPTION OF PAST AND PRESENT MEASUREMENT PROGRAMS Stations and parameters. In 1991 air quality was measured at 17 stations in Jakarta. 7 stations run by BMG (Meteorological and Geophysical Agency) and two stations run by the Jakarta Municipal Government (JMG) (before 1980 by the Ministry of Health) are permanent. 8 rotational stations are run by DKI-KPPL (District of Jakarta-Research Centre for Urban Development). The temporary nature of the KPPL sites is dictated by the availability of equipment and resources to operate the network. The location of the stations are shown in Figure 1 and a listing and description of the stations as of 1991 are presented in Table 1. The first BMG station has been in operation since 1976 and is located at the BMG Head- quarters in Central Jakarta. The six other BMG stations were started in 1980/81, but were not operated in the late 1980's. These six stations were restarted in 1991. At the BMG Headquarters TSP, NOx and SO2 are measured, while only TSP are measured at the other six BMG stations. At the BMG stations there is one 24 hour measurement every 6th day. The two stations run by the JMG are part of the United Nations Global Environment Monitoring System (GEMS) since 1979. At the GEMS sites TSP, SO2 and NO, are monitored every 6th day. DKI-KPPL operates 8 air monitoring stations on a rotational basis (i.e. every 8 days, 4 stations are operated and then the equipment is moved to 4 other stations). These stations are only operated 8 months a year. TSP, NO2, SO2 and CO (and oxidants on occasions) are measured at all sites. The location of the 8 DKI-KPPL sampling points were originally selected to record air pollution impacts on land use and are therefore not representative for most of the DKI Jakarta, notably the areas with heaviest population concentration and traffic. In the WHO/UNEP 1992 report are three of the DKI-KPPL stations characterized as road side stations (Pasar Baru, Pasar Senen and Mangga Besar) as well as the BMG Headquarters, Monas and Pulo Gadung stations. 75 76 Appendix 1 Table 1: Air gualitk monitoring network in Jakarta Station Operation Period Date Purpose/land use Remarks started discontinued restarted classification BMG Jakarta BMG Headquarters 1976 Reference/Standard-C' Operated 1976-1992, Paramater TSP, NO., SO2, acid rain, turbidity 2 particulate analysis Ancol 1980 1988-1990 1991 (July) Urban/recreation - l, C Bandengan 1980 1988-1990 1991 (April) Urban/mixed area, industry- I Giodok 1980 1988-1990 1991 (April) Urban/shopping centre, transportation - C Monas 1980 1986-1990 1991 (April) Urbanlregreening, National Monument Area recreation - C* Halim Perdana 1980 1988-1990 1991(June) Urban/airport area - C, R Kusumah Ciledug 1981 1988-1990 1991 (June) Rural area - RA Meteorological Station ................................................................................................................................................................................................... ...................................................Cass JMB/Ministry of Health Kayu Manis 1979 Urban air quality/ TSP, SO3, NOX residential area - C PuloGadung 1979 Urban air quality/ TSP, SO2, NO, industrial area - 1* JI M. H. Thamrin 1992 Urban/traffic SO2, NO, NO2, CO, PM,, ................................................... ......................................................................................................................................................... ... DKI-KPPL Pulo Gadung 1983-1990 Urban air quality/ TSP, SO2, NO., NH3 industrial & residential area - I Tebet 1983-1990 Residential - R TSP, S02, NO,, NH3 Bandengan Utara 1983-1990 Residential & TSP, S02, NO,, NH3 warehouse/urban air quality- I, C Cililitan 1983-1990 Urban air quality/bus TSP, SO2, NO,, NH3 terminal - C Pasar Baru 1983-1990 Urban air quality/ TSP, SO2, NOQ, NH3 shopping centre - C, R* Pasar Ikan 1983-1990 Urban air quality] TSP, SO2, NO., NH3 residential & warehouse - 1,C Pasar Senen 1983-1990 Urban air quality/trade TSP, SO2, NO,, NH3 centre & residential - C Mangga Besar 1983-1990 Urban air quality/trade TSP, SO2, NO., NH3 centre & residental - C* Note: Land use classification -- R, residential; RA, rural area; I, industrial; C, commercial; * roadside station. URBAIR-Jakarta 77 Figure 1: Air quality monitoring networks in Jakarta r~~~~~~~-~~, OG B Ha7 QE 2 E) Halim Perdana 4Pa0 2 B an Stations operated by BMG Stations operated by DKI A Ancol KPPL B Glodok I PasaroIkan C BMG Head Quarter 2 Bandengan Delta D Monas 3 Mangga Besar E Halim Perdana 4 Pasar Baru F Bandengan 5 Pasar.Senen G Ciledug 6 Pulo Gadung (bus terminal) 7 Cililitan Stations operated by JMG 8 Tebet H JI M.H. Thamrin 9 Pondok Gede I Kayu Manis 10 Radio Dalam J Pulo Gadung 11 PT. JIEP Note: The PT. JIEP and BMG Bandengan stations are not marked on the map because the positions are uncertain. 78 Appendix 1 DKI-KPPL has had continuous instruments for several years, but have only used these for short term special studies. The limited operation is because of the operating/maintenance cost and the availability of calibration gases. DKI-KPPL has received continuous monitoring equipment from Japan for measuring 03, SO2, NO2, and CO, and this equipment has been put into operation at the Jl M.H. Thamrin by JMG (see below). In addition to the permanent and rotational stations in Jakarta, several short-term air quality monitoring studies have been done in selected cities. Two earlier short-term studies of interest are the transportation study in Jakarta in August-September 1982 by BMG and the Ministry of Communications, and a study in 1984 in 15 centers in Indonesia by BMG, KLH (State Ministry for Population and Environment), Ministry of Health and DKI. In December 1991-February 1992, a transportation related air quality study was done in Jakarta and Bandung by the BAPEDAL (Environmental Impact Management Agency) with the assistance of ITB (Bandung Institute of Technology) and DKI-KPPL. Measurement and analyses methods. The measurement Table 2: Measurement methods used in Indonesia methods used by the various Parameter Analyses method agencies are based on the Sulfur dioxide ($02) Pararosaniline method collected in midget impinger. WHO methods and are listed Carbon monoxide (CO) Detector tube method (i.e. Draeger tube). in Table 2. Nitrogen oxides as NO2 Saltzman method collected in midget impinger. Continuous monitoring Oxidant as 03 NBKI method collected in midget impinger. _ontmuods havembeenous oin a Suspended particulates (TSP) Gravimetric. High-volume sample. mnethods have been used on a limited basis in the past in Jakarta, but their use has been restricted due to the availability of calibration gases and resource constraints. The recent BAPEDAL study noted above utilized a combination of continuous and wet chemical sampling methods. Special road side station at Ji M.H. Thamrin. Since April 1992 the JMG has been measuring air pollution from road traffic by a new display monitoring station at JI M.H. Thamrin. This station is the only one in Indonesia using modem technology and located to record road side air pollution. The pollutants measured are SO2, NO, NO2, CO and PM1o. For suspended particles, only particles below 10 pm (PM1O) in diameter are recorded as opposed to other TSP (total suspended particulates) air concentration data available in Indonesia, which include all particle sizes up to 50-100 pg//m3. The PM,0 is of special interest when relating health effects to air particle pollution. Also heavy metals are sampled and analyzed monthly in Japan where the monitoring equipment originates. ANALYSIS OF MEASUREMENT RESULTS Long term monitoring networks in Jakarta. At the BMG and JMG stations 24-hour samples are taken every 6 days. TSP, S02 and NO2 are measured at three stations and only TSP at the other six stations. The 8 DKI-KPPL stations are operated every 8 days on a rotational basis and TSP, SO2, NO2, CO and 03 are measured. In general these three agencies use the standard reference methods recommended by the WHO and/or the USEPA. Generally, flow calibration is made on URBAIR-Jakarta 79 the instruments every 6 months. Calibration procedures for the gaseous sampling (SO2 and NO2) would follow the WMO/WHO requirements. A new station at Ji M.H. Thamrin with continuous monitoring equipment was put in operation in April 1992. Total suspended particulates (TSP). Annual averages of total suspended particulates in Jakarta are shown in Tables 3 and 4. Some results from the new display monitoring station J1 M.H. Thamrin are shown in Table 5. The results show that TSP is generally very high in all areas. The 1991 value from Glodok (648 ptg/M3) exceeds the proposed national ambient air quality annual standard of 90 [tg/m3 by as much as a factor of 7. All stations, with the exception of the Halim Perada location, exceed the standard at least by a factor of 2. Table 3: 1980-1991 Annual average total suspended particulates (pg/rn3) in Jakarta for permanent BMG and Health Stations Location BMG Ancol Bandengan Glodok Monas Halim P. Ciledug Kayu Pulo Year (C) (VC) (Delta) (I) (C) (C) (CIR) (RA) Manis* (C) Gadung* (I) 1980 197.9 139.2 474.9 508.2 123.9 108.4 - 256.2 177.9 1981 337.0 117.1 409.6 455.9 142.1 98.4 73.0 223.0 164.3 1982 272.2 336.3 512.3 516.9 199.0 129.4 133.5 278.0 223.0 1983 169.5 382.6 606.4 492.1 332.2 144.1 156.0 338.2 310.3 1984 169.7 161.7 447.1 487.8 167.2 160.3 135.5 272.7 151.8 1985 150.5 158.5 468.7 450.3 284.8 120.2 155.1 213.0 184.0 1986 117.7 146.3 540.5 395.9 - 140.0 213.3 191.0 185.0 1987 175.2 169.0 272.8 390.4 - 212.3 266.4 148.0 181.0 1988 228.1 - - - 194.0 - - 188.0 187.0 1989 186.1 - - - - - 238.0 252.0 1990 168.5 - - - - - - 188.9 227.0 1991 182.2 261.2 458.8 648.3 205.8 156.4 276.2 159.0 270.0 Average 189.9 231.3 463.7 555.3 206.0 147.8 219.1 224.4 208.9 Note: Land use classification: R--residential area; I--industrial area; C--commercial area; RA--rural area; * Ministry of Health (JMG) (GEMS). Table 4: Comparison of annual averages for TSP, S02 and NO. for the periods 1986/1987, 1990/1991 and 1992/1993 for DKI-KPPL monitoring network in Jakarta Pollutants TSP (pg/r3) SO, (ppb) NO, (ppb) 19861 19901 1992/ 1986/ 1990/ 1992V 1986/ 1990/ 1992/ Stations 1987 1991 1993 1987 1991 1993 1987 1991 1993 Pasar Ikan (I/C) 220 570 536 8 3 2 9 19 58 Bandengan (I/C) 420 520 453 7.2 5 3 11 15 62 PasarSenen (C) 300 295 270 5.5 3 1 9 19 51 Pasar Baru (C/R) 220 400 353 6 3 2 2 15 66 Mangga Besar (C) 180 200 7 2.5 9 11 Cililitan (C) 170 360 5 3 10 17 Pulo Gadung (I) 160 270 367 6 4 2 9 12 78 Tebet (R) 160 250 207 3.5 5 2 6.5 9.5 42 Note: Land Use Classification:R --residential area; I--industrial area; C:--commercial area. 80 Appendix 1 Table 5: Display monitoring station, JL. Mh. Thamrin. Daily averages, Thursdays, thefirst two months of monitoring, 1992 Day SO2 NO NO2 NO, PMlg CO (ppb) (ppb) (ppb) (ppb) (pg/m3) (ppm) 16 April 14.0 138.0 75.3 213.0 92.8 5.40 23 April 7.3 138.0 46.1 185.0 33.7 5.05 30April 7.7 105.0 46.0 151.0 67.0 3.43 7 May 7.4 103.0 44.7 147.0 96.5 3.60 14 May 18.4 113.0 83.2 197.0 111.0 4.80 21 May 13.0 85.0 61.0 147.0 79.0 3.00 28 May 12.0 74.0 71.0 145.0 109.0 3.00 04June 13.1 101.0 61.7 163.0 98.3 3.93 11 June 13.0 71.0 49.7 120.0 106.0 2.42 18 June 13.2 92.5 72.1 164.0 114.0 3.35 25 June 22.1 136.0 92.7 228.0 77.2 4.9 Average 12.8 105.1 64.0 169.1 89.5 3.9 Note: PM10 data for 11 June is computed as an interpolation. Hourly monitor results 25 June 1992 Hour SO2 NO NO2 No, PM10 CO (ppb) (ppb) (ppb) (ppb) (Pg/m3) (ppm) 1 10 32 32 64 30 1.2 2 9 36 32 68 30 1.3 3 8 16 22 38 30 0.5 4 9 65 23 88 10 1.5 5 11 150 49 199 30 3.6 6 18 230 112 342 65 7.8 7 24 218 145 363 95 8.1 8 21 140 118 258 110 5.0 9 20 164 138 302 65 5.4 10 29 162 162 324 -60 6.2 11 40 190 106 296 100 6.3 12 26 192 130 322 70 6.5 13 26 178 157 335 90 6.3 14 42 178 152 330 100 6.4 15 64 204 178 382 100 8.2 16 70 190 106 296 110 7.7 17 27 160 122 282 100 7.7 18 15 190 114 304 100 7.5 19 13 124 86 210 95 4.4 20 15 218 95 313 90 8.2 21 14 128 56 184 150 4.0 22 11 56 31 87 140 1.7 23 1 18 25 43 60 0.8 24 1 1 28 34 62 25 0.8 Average 22.25 136.13 92.71 228.83 77.29 4.88 Daily (24 hour) average, high and low values, week 22-28 June, 1992 NO, (= N02 + NO), ppb PM10i pg/m3 Day Average High Low Average High Low Monday2216 196 302 58 116.0 200.0 45.0 Tuesday 23/6 196 302 58 116.0 200.0 45.0 Wednesday 24/6 212 348 84 123.0 200.0 60.0 Thursday 25/6 229 382 38 77.2 150.0 10.0 Friday 2616 210 363 0 81.0 130.0 40.0 Saturday 27/6 163 275 62 80.0 110.0 40.0 Sunday 2816 106 168 76 73.7 120.0 30.0 Source: KPPL. URBAIR-Jakarta 81 The TSP levels from the DKI-KPPL stations are not directly comparable to the BMG/Health results, because the DKI-KPPL represents different sampling locations and time periods, i.e. dry/wet seasons for each year. But there are similar trends in TSP levels between the three networks. The 1990/91 annual TSP averages in the Pasar Ikan and Bandengan areas exceeded the national ambient air quality standards by about a factor of 6. Also Table 4 shows the increasing average TSP concentrations from 1986/87 to 1990/91 for all stations, except for Pasar Senen which stayed at essentially the same level. Figure 2 shows annual average TSP concentrations for the period 1980-1991 for some selected stations in the BMG/Health network. The Glodok location (commercial, W. Jakarta) is in the most polluted area and the Halim Perada location (commercial/residential, E. Jakarta) has the lowest concentrations. Figure 2: Annual average TSP concentrations for the period 1980-1991 for some selected stations (pg/n3) 700 Annual Average Total Suspended Particulates in Jakarta Gilodok 400 - ,8MG e I00 K yuManis L) 200 *_ _ 'Halim 0 1980 1981 1982 1983 1984 1985 1985 1987 1988 1989 1990 1991 Year Figure 3 shows TSP isopleths based on the measurements in the years 1980-1985 (Office of State Min. of Population and Environment, 1990). The areas of highest TSP levels are the city Centre and the eastern part of western Jakarta. The TSP levels are much lower in the eastern parts of the city where the GEMS sites are located. There is limited information on the 24 hour average TSP levels. According to Kozak and Sudarmo (1992) the daily TSP concentrations in Jakarta exceeded the 24 hour TSP air quality guideline on the average 173 days per year over a 7-year period. The 24-hour mean TSP values from 4 selected stations, Pasar Ikan, Bandengan, Pasar Baru and Pasar Senen for the period 1992/1993 are shown in Figure 4. Most of the 24-hour mean TSP values are well above the proposed national ambient air quality standard of 230 pg/m3. The highest value of 865 pg/m3 was measured at Bandengan on 4 March 1993. At the new display monitoring station JI M.H. Thamrin near a roundabout in central Jakarta, PM1o is continuously monitored on an hourly basis. PM1o is the sum of particles with diameter less than 10 pm and is more related to possible health effects of particles in the air. PM1O daily levels at JI M.H. Thamrin station in April-June 1992 varied between 34-114 pg/m3 with an average of 90 pg/m3. The WHO 24-hour guideline of 70 pg/rn3 was exceeded most of the days. PM1o levels are somewhat lower during weekends than during working days. 82 Appendix 1 Figure 3: Suspended particulate matter isopleths 1980-1985 oTangerang O&Gok ,_a~~:0, Kayu0 Man;f;05 :0Sisi f o Ciledug N Source: Office of State Ministry of Population and Environment (1 990). The PMIO levels were considerably higher during working hours than during the night, indicating human activities (probably mainly road traffic) to be the main emission source. The PM10 data from JI M.H. Thamrin station indicate that PM,, levels in Jakarta are very much lower than TSP levels measured at all the other stations. There is no reason to believe that TSP in traffic-exposed central Jakarta areas should be lower than at the TSP stations. If the TSP measurements are correct, the obvious conclusion is that most of the TSP particles have a diameter above 10 jim. Suofur dioxide (SO2). Long-term SQ2 data is available from BMG (one station), JMG (2 stations) and KPPL (8 stations). TSP (uO/m3) TSP (u9/m3) - SP (ugom3) |SP (ug/m3) ~~~WO~~8 ( 0 JO( o888 88~~8880 8888 880 o c 0888H 0008 920825 920825 920825 920825 4 920902 920902 920902 920902 , 920909 920909 920909 920909 ~ 920917 920917 920917 920917 920925 920925 920925 I920925 9009200921010 921010 921019 921019 921019 921019 921027 921021 921027 921021 921104 921104 921104 1921104 921112 921112 921112 921112 921120 921120 921120 921120 921128 921128 921128 921128 921206 921206 921206 921206 1 921214 921214 921214 921214 921222 921222 921222 921222 921230 921230 921230 921230 , 930105 930105 930105 930105 930115 930115 930115 930115 o 930123 930123 930123 930123 i; 930131 930131 930131 930131 m 930208 930208 930208 930208 930216 930216 930216 930216 a 930224 930224: 930224 930224 930304 930304 930304 930304 930312 930312 930312 930312z 930320 930320 930320 930320 3 930329 930329 930329 930329 Z' 00 84 Appendix 1 Annual SO2 averages are shown in Tables 4 and 6. Generally the annual levels are very low, from 5 Table 6: Comparison of annual SO2 ppb (14 pg/rM3) to less than 0.1 ppb (0.3 pg/m3). The concentrationsfrom 1986-1991, from JMG stations Pulo Gadung and Kayu Manis show BMG and Ministry of Health air significantly lower values than all other stations, monitoring stations in Jakarta even in the same areas. According to Kozak and S02 (ppb) Sudarmo (1992) this could be due to specific Year Monitoring stations sampling location characteristics, but it might be BMG-HQ Kayu Manis Pulo Gadung also due to varying sampling and analysis 1986 2.0 0.1 0.2 performance by the various agencies. They point out 1987 1.4 0.1 0.2 that consistent siting criteria and inter-laboratory 1989 1.8 0.1 0.1 comparisons should be considered to resolve these 1990 4.0 <0.1 <0.l differences. 1991 2.0 <0.1 0.1 There is little available information on 24-hour average SO2 values from the BMG/JMG/KPPL networks. In 1983 maximum 24-hour average concentrations of SO2 were reported to be around 240 pg/m3, but daily averages decreased to 8 pg/m3 in 1986-1989. This remarkable sudden change cannot be explained at this time. The 24-hour mean SO2 values from 4 selected stations, Pasar Ikan, Bandengan, Pasar Baru and Pasar Senen for the period 1992/93 are shown in Figure 5. Most of the values are below 5 ppb (14 pg/m3). The highest value was 15 ppb (40 Vg/m3). The available 24-hour data suggest that SO2 concentrations in Jakarta is probably not a serious problem. Large differences in SO2 concentrations, both in time and between agencies, however, make the question of the reliability of the measurements important. Recent data from the monitoring station at Ji M.H. Thamrin in April-June 1992 show daily mean values in the range 7.3-22 ppb (about 20-60 pg/m3) with an average of 12.8 ppb (about 35 pg/m3) (see Table 5). Hourly data from June 25 indicate SO2 levels about 20 pg/m3 in the night and up to almost 200 pg/m3 during the day. The JI M.H. Thamrin site SO2 data may indicate that the 24-hour SO2 data from the other stations are too low. Sampling procedures and analysis meth- ods should be seriously checked. S02 (ppb) S02 (ppb) S02 (ppb) S02 (ppb) o"*oo";0~~~~~' , ,0,O 0O o"oeo* g"o o ow o S"CD booro r6 'No , 920825 920825 920825 920825 920902 920902 920902 920902 - 920909 920909 92090 920909 j '- 920917 920917 92097 920917 . _t 920925 920925 920925 'N 920925 i 921010 3 921010 921010 921010 921019 921019 921019 921019 921027 921027 921027 921027 921104 921104 921104 921104 921112 921112 921112 921112 921120 921120 921120 921120 921128 921128 921128 921128 921206 921206 921206 921206 921214 921214 921214 921214 921222 921222 921222 921222 921230 921230 921230 921230 930105 930105 930105 930105 930115 930115 930115 930115 930123 930123 930123 930123 930131 930131 930131 930131 930208 930208 930208 930208 930216 930216 930216 930216 930224 930224 930224 930224 930304 930304 930304 930304 930312 930312 930312 930312 930320 930320 930320 930320 930329 930329 930329 930329 00 nh 86 Appendix 1 Nitrogen dioxide (NO2). NO,, data for KPPL and Table 7: Comparison of annual NOx BMG/health stations are presented in Table 4 and averages for 1986-1991 at BMG and Table 7 respectively. NOx is reported, but the main Minis. of Health air monitoring component would probably be NO (Kozak and stations in Jakarta Sudarmo, 1992c). NOX(ppb) The JMG (GEMS) reported annual mean NO,,itor sttin concentrations of 2-4 pg/rm3, and maximum 24-hour Year BMG-HQ Kayu Manis Pulo Gadung concentrations of 5-10 Vg/m3 during 1986-1989. 1986 60 20 21 These stations are located away from the city Centre 1987 130 18 15 and thus primarily reflect suburban ambient air 1988 140 12 10 pollution. 1989 140 12 10 During 1989 and 1990 the average concentration 1990 40 10 29 at the Bandengan station in the city Centre was (as low as) 28 ,ug NO,,/m3. DKI-KPPL stations show a remarkable fall in NO,, concentrations from 113 Pg/M3 in 1983 to 9.4 Rg/M3 in 1986, and similarly, maximum 24-hour values fell from 395 Vg/M3 to 15 ,g/m3. This sudden drop in NO, concentrations cannot be explained with the available information, but it seems likely that besides a possible improvement in air quality, the siting, sampling or instrumentation of the monitoring stations must have had a major influence (WHO/UNEP, 1992). The DKI-KPPL stations show an increase again in the NO, concentrations from 1986/1987 to 1990/1991 at all monitoring stations, while the SO2 levels at the same stations fell considerably in the same period. As shown in Table 4, NO, levels were considerably higher during 1992/1993 than during 1990/1991. The mean values range from about 40 ppb to 80 ppb (80-160 pg/M3). This remarkable difference in NO, levels from year to year seems difficult to explain. From April-June 1992 NO, NO2 and NO,, data from the new monitoring station Jl M.H. Thamrin show mean values of 64 ppb NO2 (about 120 pg/M3) and 169 ppb NO,, (about 320 pg/M3). NO2 daily values ranged from 46 ppb (about 85 pg/m3) to 93 ppb (about 175 pg/m3). The highest values are above the proposed Indonesian ambient air quality standard of 150 pg/m3. Hourly NO2 values on 25 June 1992 ranged from 22 ppb (about 40 Vg/M3) to 178 ppb (about 340 pg/M3). The highest values are not far below the proposed 1-hour national ambient air quality standard of 400 pg/rM3. The results from JI M.H. Thamrin indicate that NO2 concentrations in the most heavily trafficked areas in Jakarta may be above the WHO and Indonesian standards. The Jl M.H. Thamrin NO2 results indicate, as was the case with SO2, that the 24-hour NO, data from the other stations may be too low, especially at the more centrally located stations. Similarly to SO2, the NO, sampling procedures and analysis methods should be seriously checked. Ozone (03). 03 is measured at the 8 DKI-KPPL stations. In 1986-1987 annual mean 03 concen- trations ranged from 2 pg/m3 at the Bandengan location to 15 pg/m3 at the Pasar Senen location. The latter station also had the highest 1-hour concentration with 85.8 tg/M3, while the highest 1- hour value at Bandengan was as low as 8.2 pg/M3. Thus all reported 03 concentrations in Jakarta seem to be well below the proposed national ambient air quality standards. The 03 levels seem to be lower than expected, especially compared to the NO, levels. If the 03 levels are correct, the NOx levels should be considerably higher than observed at the long term stations. URBAIR-Jakarta 87 Unfortunately, 03 is not monitored at the new J1 M.H. Thamrin location. Because of photochemical reactions of NO and 03 to NO2 and high observed NO2 levels one would expect rather low 03 levels at this site, especially during day time when the traffic volume is high. 03 measurements with a continuous monitor is recommended at this site. High 03 concentrations have been measured outside the city. 100 ppb of oxidant is frequently measured at EMC in Serpong, 30 km southwest from central Jakarta (EMC, 1994). Carbon monoxide (CO). CO is measured at the DKI-KPPL network. 8-hour average CO levels were found to be around 3.5 mg/m3 in a residential area and at a bus terminal (Cililitan site), but were up to 27 mg/m3 at the Glodok station in a city Centre commercial area. This value is well above the WHO guideline and the proposed national ambient air quality standard of 10 mg/m3, indicating CO to be a problem in heavily traffic-exposed areas. The new monitoring station at JI M.H. Thamrin showed daily CO averages between 2.4-5.1 mg/m3 in April-June 1992 (one sample every 7 days) with an average of 3.9 mg/m3. Hourly values 25 June varied between 0.5 mg/i3 in the night and 8.2 mg/m3 in the afternoon. The highest 8-hour average this day was 7.1 mg/m3, and the daily average value was 4.9 mg/mr3. The JI M.H. Thamrin air inlet is 4 m above ground level, about 10 m from the edge of a traffic circle (diameter of about 100 m). Very high traffic intensity is observed in the circle. Monitoring in a street canyon with heavy traffic would probably give higher CO levels than at the roundabout location. The wind often blows from the station to the traffic circle. Lead (Pb). Average lead concentrations at the DKI-KPPL stations usually range between 0.5- 2 pg/M3. Considering the locations of the stations, Pb concentrations well above the proposed national ambient air quality standard of 2 pg/m3 for 24-hour average are to be expected in more heavily traffic-exposed areas. A study in July 1985 showed monthly Pb concentrations at three sites between 0.3-3.6 pg/m3. The values were strongly correlated to road traffic volume. PM1O samples from the new road side monitoring station J1 M.H. Thamrin are analyzed for Pb in Japan. However, no values have been released yet. These values will probably be by far the best to evaluate air lead pollution in densely trafficked areas in Jakarta. The lead content in leaded gasoline in Indonesia is reported to be 0.44 g/l for 88 octane premium and 94 octane premix gasoline. During Summer 1995, unleaded gasoline was introduced in Jakarta, in relatively small amounts. REFERENCES Environmental Management Center (EMC). 1994. "Annual Report on Air Quality Monitoring and Studies." Vol. 1. Air-Quality Laboratory, in Indonesia. Serpong. Kozak, J.H. and R. P. Sudarmo. 1992. "An overview of air pollution in Indonesia." EMDI/KDH. Jakarta. World Health Organization/United Nations Environment Programme. 1992. Urban Air Pollution in Megacities of the World. Cambridge, MA:Blackwell Publishers. World Health Organization. 1976. Selected Methods of Measuring Air Pollutants. WHO Publications-No. 24. Geneva. APPENDIX 2: AIR QUALITY GUIDELINES NATIONAL AMBIENT AIR QUALITY STANDARDS The Air Quality Technical Committee, coordinated by KLH (State Ministry for Population and Development), and with members from the relevant national departments, DKI (District of Jakarta) and selected universities was formed in 1983. This group proposed ambient air quality standards for 9 parameters (KEPMEN, 1988). These standards are listed as "Existing standards" in Table 1. Table 1: Existing (E) and proposed (P) national ambient air quality standards for lndonesia Measuring time 30 minutes 1 hour 3 hours 8 hours 24 hours 1 year Parameter Unit E P E P E P E P E P E P 802 pg/M3 900 260 300 60 CO mg/m3 30 22.6 10 NO2 pg/m3 400 92.5a 150 100 03 pg/M3 200 160 TSP pg/M3 260 230 90 Lead pg/rm3 6 2 1 HC pg/M3 160 160 H2S pg/M3 42 NH, pg/M3 1,360 Note: a) Nitrogen oxides. The Technical Committee held a series of workshops/meetings at the beginning of August 1990 to consider and evaluate the information provided by EMDI (Environmental Management Development in Indonesia) and the members of the Committee on standards/objectives used by other countries and agencies. The existing National Ambient Air Quality standards from KEP- MEN/1988 were used as the starting point for potential revisions, additions or deletions. Revised National Ambient Air Quality Standards were drafted by the Technical Committee in January 1991, after a review which included documentation from a number of international agencies and jurisdictions. In particular, recent reviews prepared by the World Health Organization (WHO) were considered in detail and modified for the air pollutants SO2, 03, CO, TSP and Pb after discussion by the Technical Committee. In October 1991 it was proposed that a standard for hydrocarbons should be added to the list of parameters. 89 90 Appendix 2 The National Ambient Air Quality Standards proposed in 1991 are also presented in Table 1 together with the existing standards. The primary purpose of the air quality standards is the protection of public health and other environmental receptors, such as vegetation, wildlife, material deterioration etc. against the adverse effects of air pollution. However, it is emphasized that the standards must also consider the prevailing exposure levels and environmental, social, economic and cultural conditions. The standard measurement methods listed in Table 2 are essentially unchanged from KEPMEN (1988). The main reference for the measurement methods is the WHO document "Selected Methods of Measuring Air Pollutants" (WHO, 1976), which specifies standard methods that are similar to those used by U.S. Environmental Protection Agency. Table 2: Standard measurement methods for proposed national ambient air quality standards Parameter Analysis method Equipment for analysis Sampling equipment Sulfur dioxide Colorimetric Spectrometric Gas sampler Carbon monoxide Non-dispersive infrared Non-dispersive infrared analyzer CO-analyzer Nitrogen oxides as NO2 Colorimetric Spectrofotometer Gas sampler Oxidant as 03 Colorimetric Spectrofotometer Gas sampler Suspended particles Gravimetric Scale High volume sampler Lead - Gravimetric Scale High volume sampler - Destruction Atomic absorption High volume sampler VHO AIR QUALITY GUIDELINES AND STANDARDS WHO Air Quality Guidelines and standards are listed in Table 3. For SO2 the WHO guidelines are much lower than the proposed Indonesian standards for averaging periods 1 hour and 24 hours. The Indonesian CO values for 1 hour and 8 hours are equal to the WHO values. The Indonesian NO2 1 hour value is the same as the WHO guideline. The proposed Indonesian 03 1 hour guideline is within the WHO guideline range. The proposed 1 year value for lead is the same as the upper range WHO level. This is also the case for the proposed 24 hours and I year Indonesian guidelines for TSP. Generally, the proposed Indonesian National Ambient Air Quality Guidelines follow the WHO guidelines, except the 1 hour and 24 hours values for SO2. No standards are proposed for PM10, i.e. particulate matter less than 10 Pim in aerodynamic diameter. This may be because of lack of monitoring equipment. URBAIR-Jakarta 91 Table 3: WHO Air Quality Guidelines/Standards (WHO, 1977a, 1977b, 1978, 1979, 1987) Parameter 10 minutes 15 minutes 30 minutes 1 hour 8 hours 24 hours 1 year Year of standard SO, jg/rM3 500 350 125a 50a 1987 SO, jg/rn3 100-150 40-60 1979 BS6 jig/m3 125a 50a 1987 BSb jig/M3 100-150 40-60 1979 TSP ig/m3 120a 1987 TSP jg/m3 150-230 60-90 1979 PM10 Ig/rM3 70a 1987 Lead gig/mr 0.5-1 1987,1977b CO mg/m3 100 60 30 10 1987 N02 jig/M3 400 150 1987 N02 jig/M3 1 90-320c 1 977b 03 jig/M3 150-200 100-120 1987 g jLg/rM3 100-200 1978 Notes: a) Guideline values for combined exposure to sulfur dioxide and suspended particulate matter (they may not apply to situations where only one of the components is present). % b) Application of the black smoke value is recommended only in areas where coal smoke from domestic fires is the dominant component of the particulates. It does not necessarily apply where diesel smoke is an important contributor. c) Not to be exceeded more than once per month. Suspended particulate matter measurement methods BS = Black smoke; a concentration of a standard smoke with an equivalent reflectance reduction to that of the atmospheric particles as collected on a filter paper. TSP = Total suspended particulate matter; the mass of collected particulate matter by gravimetric analysis divided by total volume sampled. PM10 = Particulate matter less than 10 jm in aerodynamic diameter; the mass of particulate matter collected by a sampler having an inlet with 50 per cent penetration at 10 jim aerodynamic diameter determined gravimetrically divided by the total volume sampled. TP = Thoracic particles (as PM10). IP = Inhalable particles (as PM10). Source: WHO/UNEP (1992). REFERENCES KEPMEN. 1988. National Ambient Air Quality Standards. The Decree of the State Minister for Population and the Environment. KEP-02/MENKLM/I/1988. Jakarta. World Health Organization/United Nations Environment Programme. 1992. Urban Air Pollution in Megacities of the World. Cambridge, MA:Blackwell Publishers. World Health Organization. 1976. Selected Methods of Measuring Air Pollutants. WHO Publications-No. 24. Geneva. APPENDIX 3: AIR POLLUTION LAWS AND REGULATIONS FOR INDONESIA AND DKI JAKARTA REGULATIONS AND INSTITUTIONS INAIR POLLUTION (1994) BY DR. BUDIRAHARDJO General information. Cities development all over the world give the consequences in transportation problems, due to the economic growth in the cities, causes the additional ownership of the vehicles and the increasing of number of population move to the suburban area for the housing and located in the distance between residential are with the center of the city and also job sites. Jakarta for example in 1985 was facing 14 million personal trips and based on the study of ARSDS, the projection is increasing to 24.9 million person trips in 2005 where the projected population is 12 million. The annual increase of cars in Jakarta is around 11.76% in average, and there are a lot of difficulties have faced to implement the limitation number of vehicles owned by citizens. It is understand able that the present traffic condition mostly congested. Will become more critical if the counter measures are not being taken to overcome the situation especially in traffic problems. The amount of vehicles on the roads and the traffic jam situation which are frequently happen is the source of emission of tail gas will cause the impact of worsening of ambient air quality. Regulations On Emission Of Exhaust Gas Handling. In the field of traffic and land transportation, there are several regulations, among other: * Act number 14 of 1992 on: Traffic and Land Transportation, in Chapter 13 article (1) mentions: "Every motorized vehicle, trailler, box car and special vehicle which are on the roads subject to be tested." Chapter 13 article (2): The testing as it is mean in the article (1) include the Type Approval and/or Periodic Test. In Chapter 50 article (1): "To prevent air pollution and noise pollution form vehicle which might bring impact to the sustainability of Living Environment, every car (vehicle) obligatory to comply to the criteria of standard emission exhaust gas and noise level." 93 94 Appendix 3 In Chapter 50 article (2): "Every owner, manager of the Public Transportation, obligatory has to prevent the happening of air pollution and noise as what is mean in the article (1), as the results of the operationalization of vehicles." Government Regulation number 44 of 1993 on Vehicles and drivers, in Chapter 127 article (1) among other mention, "Motorized vehicle has to comply with the requirement of roadworthiness, which includes: a. Emission of exhaust gas from motorized vehicle, and b. The noise of main brake. * In Chapter 127 article (3) mentions: "The criteria of roadworthiness which is mean in the article (1) a and b, will determined by Ministerial Decree who is responsible in the Living Environment after the consultation with Minister of transportation." Decree of Ministry of Transportation number KM 71 of 1993 on: The periodical test of Motorized Vehicle. In Chapter 2 article (1): Implementation of periodical test of motorized vehicle by mean of: a. to guarantee of safety in the technical point of view in the using of motorized vehicle on the road, b. to keep sustain environment from the possibility pollution due to the usage of the motorized vehicle on the road, and c. To serve the public service to the society. * In Chapter 3, Periodical test of motorized vehicle is done by Provincial Government and operationally is done by Traffic and Transportation Service in the Province, or can be delegated to Traffic and Transportation Service in Local Government Level. In Chapter 12 mentioned, The equipment for testing of exhaust gases, include testing equipment for Carbon Monoxide (CO), Hydrocarbon (HC) and Smoke tester of the exhaust gases. * Decree of Ministry of Transportation, number KM 8 of 1989, The criteria of standard limitation on the roadworthiness to the production of motorized vehicle, trailler, box car, body construction, truck body and each components, was decided the limit. The decision about the exhaust gases, was decided in Chapter 3 and Chapter 4 as follow: a. the content of CO and HC at emission of the exhaust motorized vehicle with Premium as the fuel with 87 RON has been decided maximum 4.5% for CO and 1200 ppm for HC; b. the content of CO and HC at the emission gas of motorized vehicle in idling condition and during normal atmospheric condition; c. The smoke content in the emission gas of motorized vehicle with compression ignition and with diesel fuel it was decided with maximum 50%; d. The smoke level of the exhaust gas measured in free speed condition. * The criteria of noise level of horn belong to the motorized vehicle, was decided in Chapter 7 and Chapter 8 as follow: a. the horn noise level of motorized vehicle was decided minimum 90 dB(A) and maximum at 118 dB(A); b. The decision of horn noise level of motorized vehicle be measured at the place where there is no noise with the reference noise level at the lower condition in the distant of 2 meters in front of vehicle. * Governor Jakarta Decree number 1222 of 1990, about "Standard emission of vehicle in Capital City of Jakarta" In the Chapter 4, article (1) mentioned: The Traffic and High Way URBAIR-Jakarta 95 Service Department Jakarta is responsible to exercise Verification of vehicle emission in Capital City of Jakarta. In the article (4) of the same Chapter mentioned: The implementation of emission verification will be done at the same time with roadworthiness test of the vehicle or separately. * Governor Jakarta Decree number 1236 of 1990 about operating procedure in implementing vehicle emission standard in Capital City of Jakarta. In the Chapter 6, article (1) mentioned: The control toward implementation of vehicle emission will be done by rela'.ed institution, includes: - Provincial Planning Board of Jakarta (Bappeda), - Bureau of Environment (BBLH), - Urban Research and Environment Office (KPPL), - Bureau of Economic Facilities Development (Bangsarekda), - Bureau of Well-Order (Ro Ketertiban), - Regional Investment Board (BKPMD), - Department of Health Service (DKK), - Department of Industry Service (Dinas Perindustrian), - Department of Public Works Service (DPU), - Department of City Planning Service (Dinas Tata Kota), - Bureau of Law (Ro Hukum). In Chapter 7, article (1) mentioned: Evaluation toward the emission standard will be done as follow: a. Supervising in the emission parameters evaluation will be coordinated by Urban Research & Environmental Office, b. Supervising in the implementation evaluation will be coordinated by Bureau of Environment, c. Supervising in the evaluation of regulation affair will be coordinated by Bureau of Law. Controlling Air Pollution Through Emission Examination * Procedure and Phasing of emission examination. The procedure which guides the air pollution program in administrative border of Jakarta was mentioned in Governor Decree 1222 and 1236 of 1990. In these decrees several items have to be underlined are as follow: a. the vehicles that have to be examined are all kinds of vehicle which are operated in the public roads in Jakarta includes Public cars, transportation cars, Passenger's cars, Buses, Trucks and Motor Cycles; b. every kind of vehicle in point a above, has to comply the standard in the parameters as follow; c. Transport & Highway Department Service is responsible in examination of emission in Jakarta, emission worthiness duration minimum three (3) months and maximum six (6) months. The vehicle that fails to comply with emission standard is restricted to be operated in the public roads; d. The phasing of implementation of standard emission: 1) Public enlighting and education, 2) The choice of appropriate testing equipment, 3) Planning the needs of facilities, 96 Appendix 3 4) Testing Procedures and Certification, Table 1: Mandatory standard emission tests 5) Cooperation with Standard Emission Private Sector, Type of Vehicle Fuel CO-'/%Vol NOx-ppm HC-ppm Smoke.% 6) Supervising Passenger Car Petrol 4.50 1,200 1,200 -- procedure between related Diesel - 1,200 1,200 50 institutions. Mixed 4.50 1,200 1,200 50 institutions. CNG 3.00 -- Trucks, Pickup Petrol 4.50 1,200 1,200 -- The amount of vehicle Diesel -- 1,200 1,200 50 compulsory to emission exam. CNG 3.00 -- -- -- * The amount of vehicles Buses Petrol 4.50 1,200 1,200 -- compulsory to be emission Diesel -- 1,200 1,200 50 examination and C~NG 3.00 -- -. -- examination and Motor Cycles Petrol 4.50 2,800 2,800 roadworthiness test in Mixed 4.50 3,600 3,000 -- Jakarta based on the data up to the end of 1990 are given in Table 2. - With the assumption of annual increase of vehicles that have to Table 2: Compulsory vehicle exams be examined as 8.72%, the projection will be 432,930 Amount of Vehicle Vehicle Compulsory Exam vehicles to be tested in the Type of Vehicle Amount Type of Vehicle Amount Exam comicles to (five) yearsted iPublic car 40,522 Passenger car 35,792 65,809 coming 5 (five) years. Private car 553,755 Buses 26,759 21,110 - At the same time based on the Commercial 174,494 Cargo car 134,719 197,097 assumption of vehicle Total: 1,531,645 Total: 197,270 285,016 annual increasing rate is constant follow the rate Table 3: Projected vehicles to be examined in 1990 and 1995 in the period of 1986- Type of Vehicle Annual Increasing Emission Emission Composition 1989, will give the Rate Exam 1990 Exam 1995 (%) estimation of vehicles Private cars 5.62 1,107,550 1,455,760 41.4 which will be examined Cars compulsory to 8.72 285,016 432,930 12.3 in 1995 (After stage I be examined 1991-1994) are (as Motor Cycles 1.34 1,525,748 1,630,740 46.3 Amount of Vehicles 2,918,341 3,519,430 100.0 summarized in Table 3)- Note: Assumed emission exam two times per year. Examination of motorized vehicle emission. * Principally the emission test is one of the component in roadworthiness of the motorized vehicle, based on Decree of Minister of Transportation KM 8 of 1989. Due to the most of vehicles that have to be tested are private cars (87.7%) and motor cycles, this mean that most emission test facilities have to be prepared. With the calculation of time needed for administrative affairs, at least 20 minutes for each testing. When the operation time of testing equipment is 6 hours, and 6 days week, and 50 weeks per year (2 weeks for maintenance and calibration), result of calculation is that every testing unit able to perform the testing for 1,800 hours per year or 5,400 cars per year. If the URBAIR-Jakarta 97 estimated amount of cars Figure 1: Vehicle emission responsibility that have to be Governor of Jakarta tested are 33 i million in the Urban Research& Trans & Highway Dept Bureau of year of 1995, Environment I | Service | |rEvironment the need of testing Vehicle Verification Unit Private Own Workshop equipment is - For Public Cars For Private Cars about 650 units. -- Motor Cycles This means the need of private sector participation. Supervision of emission test. * As it was mentioned in the Governor Decree number 1236 of 1990, the institution for vehicle emission test in Jakarta is as follows (Figure 1): * The related institutions in supervising various activities and each related responsibility of vehicles emission test, was mentioned in the Chapter 2 above. Air pollution control through traffic & transportation management * Air pollution control in the urbanized area might be supported by traffic management. * In the Provincial Government Act number 5 of 1984 about: Master Plan Jakarta up to the year 2005, in the policy guideline of Transportation Sector was mentioned the present of Restricted Zones in the center of the city. * The limitation of transportation was decided through the zoning. * The zoning in the center city, which surrounded by the rail way, the transportation limitation might reach up to 75%, this means the residual 25% volume of transportation in this zone. - Zones surrounded by rail way ring up to inner ring road, the transportation limitation will be 50%. - Zones in between inner and outer ring road, the limitation will 25%, and zones outside outer ring road the limitation only 5-10%. * With this limitation of transportation means the amount of operated vehicles on the public road are decreasing, this will reduce amount of pollutant from tail gas of motorized vehicle. Beside the less of amount of vehicles means the average vehicle's speed on the public road also increasing, and resulting less emission gases per unit length of road. * The experiment of Restricted Area has been exercised by "Three in One", since 20 April 1992, in the Path of Highway Sudirman, Thamrin, Medan Merdeka Barat, and Gatot Subroto from 6:30-10:00 a.m. The private cars pass through the restricted zones have to be three and more passengers. The 14 months record on the results of "Three in One" are as follow: - private vehicles speed increase by 35%, - buses speed increase by 40%, - volume of private vehicles increase by 2% but with increasing speed, - amount of buses increase by 99% (frequency of trips increase), - amount of buses passengers increase by 89%. 98 Appendix 3 * The limitation of the usage of private cars has to be balanced by the public transportation service, as such that the people able to change to the public transportation rather than using their own cars. Special Bus lane has been tried since 1 March 1990 in several path of high way like Thamrin Sudirman from 07.00-09.00 and 16.00-19.00, and gradually will be followed in other high ways like: Sisingamangaraja, Medan Merdeka Barat, Gunung Sahari up to Jatinegara, Kramat Bunder to Suprpto, Pramuka-Pemuda, Panglima Polim Raya and Melawai Raya. In the year 1993 end will be implemented in Gajah Mada-Hayam Wuruk. * By the Special Bus Lane shows some improvement as follow: - average Bus speed increase by 32%, - volume of Buses increase by 48%, - passengers increase by 42%, - amount of buses trips increase from 6 trips/day now up to 7.2 trips/day. * Mass Rapid Transportation still being considered by Central Government and Government of Jakarta Metropolitan. If the mode of Light Train or Sub Way was chosen, because both facilities are using electricity as power sources, this mean that the solution might bring the decrease of air pollution through Transportation Sector. * MRT which are present now is fly over rail way from Manggarai Gambir, Rail way ring Kota- Senen-Jatinegara-Manggarai-Tanah Abang-Kota, to and fro. Also electrically and diesel fuel Jabotabek Train. Electric wiring net work has been prepare and ready by now, excluded in Kebayoran Lama-Rangkas Bitung. • MRT also in the design state from Block M to City, to operate the facilities, an institution should be set up as Authority Agency to manage the facilities. Conclusion * The land transportation has contribute dominantly to Air Pollution in the urban area/City as the results of emission gases, while-the amount of vehicles are increasing. * And for private cars, motor cycles might invite the Private Sector to join with the emission test activities. * "Three in One" shows a good result on air pollution abatement and should be broadened in the near future. * MRT able to be the solution of transportation problem to limit the amount of private cars. and in the long run also MRT in Jabotabek Region. AIR POLLUTION CONTROL INSTITUTIONS Dinas Lalu lintas dan Angkutan Jalan Raya (DLLAJR) = Road Traffic and Transportation Department. DLLAJR-DKI is a department of the Jakarta Provincial Government which is responsible for the control of road traffic and transportation, including the road worthiness of the motor vehicles and their emission. * According to the Regulation, all cars should undergo emission test. It will be implemented in phases, with cargo and public transportation getting first priority (Hadiwinoto, MEIP). URBAIR-Jakarta 99 The organization, tasks and procedures in the DLLAJR are defined in the Perda (Local Regulation) no. 2 / 1985. The head of the DLLAJR reports to the Governor, and he is under the administrative coordination of the Sekretaris Wilayah Daerah (Secretary of the Province). The main tasks of DLLAJR are to execute/implement the planning, organizing, supervision, and control of the road traffic and transportation which are in the authority of the local/provincial government, and other tasks complying to the acts and regulations, to achieve a safe, orderly, and (smooth) traffic and transportation. To execute the main tasks, the DLLAJR will: a) plan the road and transportation network; b) implement the techniques of traffic and transportation; c) implement the licensing of traffic and transportation; d) implement the vehicle inspection; e) control the traffic, transportation, and motor vehicles; f) control and ensure the safety of road transportation, terminals and transfer points; g) plan and construct terminal and transfer points. The organization of DLLAJR comprises: a) Head of the DLLAJR, b) Deputy Head of the DLLAJR, c) Administration, d) Accounting, e) Personnel, f) Planning and Programming, g) Traffic Engineering, h) Transport Services Development, i) Traffic and Transportation Control, j) Terminal and Transfer Points Development, k) Vehicle Inspection, 1) Sub Department at the Municipality level. Divisions which are related to the air pollution control are: a) Planning and Programming Division, responsible for data collection, programming, monitoring, evaluation and control, among others traffic counting on roads and intersections for all motor vehicles. Planning and Programming Division also conduct studies on traffic volume control, development of mass transit, the use of compressed natural gas, and development of passenger and goods transport routes. b) Traffic Engineering, responsible for road marking and signs, parking sites, traffic computers, crossing design, u-turns, medians, pedestrian bridge, etc. c) Transport Services Development Division, responsible for the development, licensing and control of transport services establishment, among others: licensing for the routes and operations of bus companies, and to implement/enforce the use of natural gas for public transportation. d) Traffic and Transportation Control Division, responsible for the coordination and formulation of control, enforcement, and information on traffic and transport system, 100 Appendix 3 development and supervision of driving-schools, garages/workshops, and emission control at the terminals. e) Car Inspection Division, responsible for the inspection of motor vehicles. Trucks, buses, and other public transport vehicles get the inspection each six months (twice yearly) including emission control. The inspections are carried out at the inspection office: Pulogadung for bus and passenger cars, and Ujung Menteng for trucks. Also available are on-site inspections as requested by the car pools. f) The Sub-Departments at the Municipality level are responsible for the orderly functions of the traffic and transportation facilities, such as the control on bus, trucks, taxis, and the local traffic condition. Badan Pengelola Terminal Angkutan Jalan = Road Transportation Terminal Authority. The Head of the DLLAJ-DKI is an ex-officio head of the BPTAJ, because the functions are very closely related. The main task of BPTAJ is to optimize the capacity and outputs of all the terminal facilities to improve public service. The organization comprises: * Head of BPTAJ, * Deputy Head of BPTAJ, * Planning and Programming, * Development and Supervision, * Construction and Maintenance, * Security and Enforcement, * General Affairs, * Terminal Sites. The divisions which are closely related to air pollution control are: * Planning and Programming, which plans the operations and development of the terminals; * Security and Enforcement, which control the transport services and emission discharge; * Development and Supervision, which gives the guidelines, motivate, and supervise the transport companies on condition of the vehicles; * Terminal Sites, which conduct the daily control at the terminals, including the vehicle condition. Biro Bina Lingkungan Hidup (BBLH) = Bureau of Environment. BBLH is under the coordination of the Assistant of the Secretary for Social Welfare, at the Secretariat of the Province. Its main task is to prepare policies, coordination, and development on environmental affairs. To implement the tasks, BBLH will: a) prepare policies, programs, and guidelines on environmental quality and environmental protection; b) coordinate, guide, and encourage environmentally sound development; c) coordinate, plan, and guide development of man-made environment; d) coordinate, plan, and guide implementation and enforcement of pollution control. The organization of BBLH comprises: URBAIR-Jakarta 101 a) Human Settlements Figure 2: The organizational structure of the Bureau of Environment Division, Secretary b) Man-made of the Provincial Govemment l Environment Division, Assistant Other c) Natural for Social Welfare | Assistants Environment | Division, Bureau of Environment d) Control Division. Human Settlements Man-made Env. Natural Environment Control There is no Division Division Division Division specific division for Planning Section Environmental Conservation Cleanliness & Slum air pollution Impact Analysis Section Improvement control, but it is Development Pollution Rehabilitation Water included in the task Section Control Section Supply Administration Education Natural Resources of the Man-made Section and Information Section Environment Division which is responsible for data collection, planning, programming and development of pollution abatement. The Pollution Control Section in the Man-made Environment Division is in charge of: a) data collection, programming, and preparing guidelines for the development of pollution control; b) coordination for implementation of pollution control. The structure is rather confusing and needs some adjustment. Direktorat Jendral Perhubungan Darat (DJPD) = Directorate General for Land Transport. DJPD is a Directorate General under the Ministry of Transportation responsible for road transportation, railway, and ferry. The development of the Urban Mass Transit System (Sarana Angkutan Umum Massal = SAUM) will help reduce the air pollution in urban areas. Without an adequate mass transit system the growing metropolis will depend only on road transportation, especially private cars. Traffic jams and air pollution has been worsening continuously. A breakthrough is critically needed to reduce traffic jams and air pollution, giving priority to public transport, especially the mass transit system. APPENDIX 4: EMISSIONS SURVEY FOR JAKARTA INTRODUCTION This emissions survey is prepared to serve as input for model calculations for the Jakarta area, as a tool in developing an Air Quality Management Strategy (AQMS) for the area. In order to use it as a tool it is necessary to have correct information about the present emissions situation (amounts and spatial distribution) and the effects of different development strategies. Model calculations together with air quality measurements will give a description of the present situation, and the model may be used later to range the different alternatives for the future. An emissions inventory should cover source groups as industrial point sources, small industry and domestic emissions and emissions from main road and local road traffic. It is impossible to calculate the emissions from each single source (house, stack, car), but using representative emission factors will normally give very good estimates. The emissions in a city may be organized in three main groups: traffic, industrial and domestic activities. For model calculations it is necessary to calculate both total emissions for each group and the spatial distribution of the emissions. This survey is not a complete emissions survey for Jakarta. It is based upon data which are not satisfactory explained and errors may have been introduced. Many source groups are not included yet, and for other the calculations are based upon secondary information, specially for the spatial distribution. This means that many basic input data are still missing, and we have had to use other data than desired to calculate the distribution. MAP AND EMISSIONS GRID The emission calculations were intended to be made for a 1 km2 grid of 32 x 32, using the UTM net according to "Peta Rubumesi Indonesia" 1:25,000, edition 1990. All road coordinates and references are given relative to these maps. Figure 1 shows the DKI Jakarta Region and the grid net, which covers 1,024 km2. DKI Jakarta itself covers about 666 km2, the rest is areas in Bekasi, Bogor, Tangerang and sea. The district borders in the figure are drawn directly from reduced copies of the maps. 103 104 Appendix 4 Figure l-Districts in Jakarta and the Soedomo grid Note: P: Central Jakarta, S: South Jakarta, T: East Jakarta, U: North Jakarta, B: West Jakarta. Source: Bachrun (1991). For this study, basic data for calculating emissions for many source groups were not available in the first phase. For these we had to make use of data from Dr. Soedomos estimates of the emissions in Jakarta (Soedomo, 1992). He uses a grid network of about 1500 x 1500 in2, and we found it difficult to transform his data to the km2-grid. Instead it was decided to use the Soedomo URBAIR-Jakarta 105 grid for the calculations. In the UTM-system this corresponds to a zero-point in the lower left corner with UTM-co-ordinates (686, 9295). As air pollution moves across all administrative boundaries, an emissions survey has also to take into account activities in the surroundings of Jakarta, but the most dominant work has to be made for Jakarta itself. Near the border of Jakarta there are industrial activities, mainly along the main roads to the east, south and west of the metropol. The new Jakarta International Airport Soekarno-Hatta is also situated outside the border east of Jakarta, in Tangerang. POPULATION DISTRIBUTION Many of the emitting activities in a city are distributed according to the population distribution, and the exposure calculations use the population distribution directly. The evaluation of the population distribution is based upon data from the census 1990 (Jakarta Statistical Office, JSO, 1991) and the Jakarta maps showing the borders of the different districts and sub-districts. For each sub-district there was evaluated a distribution code to the grid net, and the population within the sub-district allocated to the grid according to this. This is a method which gives a fairly correct distribution; the more complete the information upon which the distribution code is based, the more correct will the result be. The errors will be of the order of locating some hundreds of inhabitants in one grid instead of the neighboring grid. When the distribution code has been made, it is easy to make new distribution calculations with new population data, e.g. future projections. It is only when there have been (or are planned) major changes within a sub-district that the distribution code has to be revised. The population in grid (I,J) within sub-district K will be: POP(I,J) = INH(K)*COV(I,J,K), where * INH(K) is the number of inhabitants in the sub-district K, * COV(I,J,K) is the coverage of grid (I,J) to sub-district K, * LCOV(I,J,K) =1.0. In different data sets for the population of Jakarta the area of each region and sub-region varies, often considerably, from data-source to data-source. It is not known whether this has to do with new administrative borders or different reference maps. Table 1 shows the land area and the population for the districts (kecamatans) in Jakarta according to different sources. There are large differences between the data sets which cannot be explained only by migration or development. To produce a correct population distribution it is necessary to check the background for the input data very strictly. In the calculations we have used data from JSO 1991; for some of the kelurahans we have used areas according to the map and other sources. Figure 2 shows the calculated population distribution for Jakarta 1990. 106 Appendix 4 Table 1: Populationin the regions of Jakarta according to different sources Central Jakarta (Jakarta Pusat) km2 kel. 1987 1990 1990 stat Tanah Abang 9.30 7 229,896 192,152 203,975 Menteng 6.53 5 116,581 90,774 117,415 Senen 4.23 6 134,547 112,589 130,256 Cempaka Putih 4.69 3 84,400 92,497 88,242 Johar Baru 2.38 4 112,850 122,866 106,847 Sawah Besar 6.22 5 152,040 124,482 146,455 Gambir 7.80 6 129,493 112,864 127,021 Kemayoran 8.21 8 206,107 226,528 228,457 Jakarta Pusat 49.36 44 1,165,914 1,074,752 1,148,669 Jakarta East (Jakarta rimur) km2 kel. 1987 1990 1990 stat Pasar Rebo 12.95 5 80,366 119,517 99,431 Cipayung 27.21 8 55,939 100,860 71,449 Ciracas 16.09 5 94,709 157,674 122,372 KramatJati 13.34 7 159,711 211,757 175,521 Makasar 21.64 5 117,989 146,532 134,224 Jatinegara 10.64 8 253,682 277,578 266,335 Duren Sawit 23.13 7 205,068 290,246 241,577 Matraman 4.85 6 176,205 165,372 179,595 Pulo Gadung 15.71 7 229,115 279,103 251,313 Cakung 42.43 7 119,112 315,826 191,284 JakartaTimur 187.99 65 1,491,896 2,064,465 1,733,101 Jakarta West (Jakarta Barat) km2 kel. 1987 1990 1990 stat Kebon Jeruk 17.87 6 144,399 261,605 165,479 Kembangan 24.64 5 81,043 157,233 99,856 Cengkareng 30.10 6 130,868 367,969 178,087 Kalideres 27.39 5 94,147 175,496 102,712 Grogol Petamburan 11.39 6 224,316 242,015 221,188 Palmerah 7.54 5 186,090 217,065 191,625 Tambora 5.48 11 243,242 263,607 266,499 Taman Sari 4.36 8 155,534 130,326 152,205 Jakarta Barat 128.77 52 1,259,639 1,815,316 1,377,651 South Jakarta (Jakarta Selatan) km2 kel. 1987 1990 1990 stat Kebayoran Lama 19.31 6 210,805 260,764 262,722 Pesanggrahan 13.46 5 89,891 153,715 125,705 Pasar Minggu 22.71 7 224,038 231,848 203,519 Jagakarsa 25.51 5 111,812 143,072 127,505 Mampang Prapatan 7.73 5 127,758 148,665 125,242 Pancoran 8.23 6 112,786 141,373 123,333 Kebayoran Baru 12.75 10 199,175 186,865 198,033 Setia Budi 9.05 8 179,405 185,959 Tebet 9.53 7 248,493 273,961 Cilandak 18.35 5 166,550 172,036 147,706 Jakarta Selatan 146.63 64 1,866,236 1,773,685 URBAIR-Jakarta 107 Table I continued: Population in the regions of Jakarta according to different sources Jakarta North (Jakarta Utara) km2 kel. 1987 1990 1990 stat Penjaringan 35.48 5 155,630 158,798 Pademangan 9.91 3 118,203 90,505 120,317 Tanjung Prok 25.22 7 250,024 277,372 284,654 Koja 11.38 6 226,160 241,833 246,975 Kelapa Gading 16.12 3 59,253 67,305 71,604 Cilicing 43.29 7 161,879 177,214 178,628 Pulau Seribu 11.80 4 14,467 14,246 14,276 Jakarta Utara 153.20 35 1,024,105 1,075,252 Total 665.95 260 7,844,874 7,108,358 Note: kel. - number of kelurahans. Sources: for 1987: Bachrun et al. (1991); for 1990: Soedomo (1993); for 1990 stat: JSO (1991). The same procedure may be used for distributing other types of data, using demographic or socio- economic data. For example the use of different fuels may be a function of social standard. Figure 2: Population in Jakarta 1990 (in hundreds of inhabitants) MAP FOR INHABITANT UNIT: PERSON HIGHEST VALUE IS 1.2044E+05, IN ( 11 , 15) SUM= 7.10835E+06SCALE: 1.OE+02 GRID SIZE: 1500 METER 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 J=20. . 1. ............... 3. 6. J=19 39. 47. 23 5. 2. 4. . . . . . . 76. 162. 63. 173. 63. 41. 9. J=18 64. 107. 104. 32. 7. 39. 157. 255. 255 . 195. 139. 426. 822. 673. 398. 217. 28. 10. J=17 51. 72. 117. 130. 94. 22. 123. 558. 528. 540. 390. 100. 392. 493. 772. 278. 351. 306. 42. 24. J=16 78. 97. 87. 106. 145. 202. 469. 459. 790. 898.1045. 397. 147. 147. 131. 137. 39. 39. 39. 29. J=15 72. 110. 116. 92. 92. 356. 635. 722. 565. 395.1204. 855. 635. 316. 122. 132. 65. 43. 37. 26. J=14 43. 105. 84. 69. 111. 193. 370. 828. 651. 228. 813. 895. 638. 356. 199. 151. 96. 45. 35. 90. J=13 35. 49. 49. 189. 370. 778. 730.1098. 489. 486. 499. 636. 392. 231. 252. 127. 104. 97. J=12 40. 190. 112. 225. 227. 974. 758. 763. 585. 945. 865. 708. 520. 194. 155. 81. 81. 37. J=11 59. 97. 116. 250. 260. 348. 565. 729. 682. 768. 933. 682. 384. 341. 341. 325. 169. J=10 . . . . .129. 263. 291. 313. 407. 399. 888. 863. 840. 711. 357. 268. 211. 209. J= 9 . . . . .79. 240. 298. 445. 402. 139. 557. 452. 527. 513. 66. 175. 153. 112. J= 8 . . . . .29. 303. 159. 380. 396. 118. 672. 319. 425. 369. 66. 31 J= 7 . . . . .47. 199. 129. 204. 257. 253. 313. 208. 228. 268. 62. 52 J= 6 . . . . . .82. 123. 258. 213. 200. 228. 304. 255. 272. 177. 63. 16. J= 5 . . . . . . .73. 105. 112. 144. 188. 207. 287. 181. 164. 76. 32. J= 4 . . . . . . . .23. 25. 67. 155. 237. 252. 49. 82. 60. 32 J= 3 . . . . . . . . .44. 91. 78. 137. 132. 94. 55. 32. 12 J= 2 . . . . . . . .10. 55. 64. 56. 88. 89. 58. 33. 11 J= 1. . . . . . . 6. 41. 25 . . 30. 66. 20. 7 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 Source: JSO (1991). 108 Appendix 4 EXHAUST EMISSIONS FROM TRAFFIC Total traffic work. To make an estimate of total traffic work and emissions from traffic a normal approach is to use the number of registered cars of different categories together with an estimate of an average annual driving distance (AADD) for each vehicle category as the basis for the estimates. In many cases, however, AADD is not known and estimates show large differences from city to city. The following estimate for the annual average daily traffic Table 2: Distribution of vehicle categories in the urban traffic of (AADT) in Jakarta is Jakarta instead based upon data Sedan+ Pickup Bus Microlet + Truck Truck MC Bajaj for the yearly gasoline Taxi Metro Mini Gandeng consumption, 1,175 x .5083 .0524 .0216 .0425 .0138 .0002 .3189 .0423 103m3 in 1990 (JSO, Note: Values are normalized with respect to the total traffic intensity. 1991). Soedomo has reported counts of different vehicle categories for morning (07-09), daytime (12-14) and afternoon (16-18) traffic at 22 different roads in Jakarta (Soedomo, 1993), and from the sum of all counts for each vehicle category an average vehicle distribution is calculated, as shown in Table 2. This traffic composition is based upon counts at only a few roads, many of them with restrictions for certain vehicle types. The main road network in Jakarta should be classified into different road classes and for each road class separate vehicle distributions should be calculated. Also, hourly counts should be performed for 24 hours at several (10 or more) roads, in order to study the representativity of short-time counts. The EPA reports the following fuel consumption for Indonesian vehicles (Bosch, 1991), taken from the Highway Transport Planning Project 1986 (Assumed average speed is 30-40 km/h): * Car: .171 l/km (80% gasoline/20% diesel). * Truck: - Pickup-.171 1/km (50% gasoline/50% diesel), - Medium-.181 1/km (20% gasoline/80% diesel), - Heavy-.236 1/km (0% gasoline/100% diesel). * Bus: - General-. 191 l/km (0% gasoline/100% diesel), Table 3: Specific gasoline consumption in Jakarta - Oplet/Sudaco-.181 l/km -31 gpetsdaolie.9 181se/km Vehicle group Fraction Gasoline Consumption Consumption (31% gasoline/69% diesel), of traffic fraction Ukm Il/year* * Motorcycle: .0201/km (100% Sedan/Taxi .5083 0.8 .171 .06953 MT gasoline/0% diesel), Pickup .0524 0.5 .181 .00474 MT * Becak: .020 1/km (100% Truck, med. .0138 0.2 .200 .00055 AAT gasoline/0% diesel). Bus, small .0425 0.31 .181 .00238 MT This gives a gasoline BajaiMC .3612 1.0 .020 .00722 AAT SUM 0.810 1,175 x 10QB l** .08443 AAT consumption for each group as - * The total traffic work for the gasoline cars. shown in Table 3. ** Total annual consumption Compared with the total gasoline consumption this gives URBAIR-Jakarta 109 the total traffic work for the gasoline cars. * AAT = 13,917 x 1 Ocar-km/year and the annual average daily gasoline traffic, * AADT = 38.129 x 106 car-km/day. According to Table 3 the gasoline cars represent 81% of the total traffic work, and this gives a total traffic work of 17.181 x 109 car-km/year or 47.073 x 106 car-km/day. The validity of this approach is dependent upon correct consumption figures for gasoline, accepted consumption factors, correct statistical data for gasoline/diesel composition for each vehicle group and a traffic composition based upon sufficiently complete traffic counts. As explained, there are however, shortcomings in the data basis that needs to be improved, e.g. more counts and data for traffic compositions. Following the same procedure for diesel, we get a diesel consumption factor of 0.0336 1/km, which should give a diesel consumption of 110 x 103 m3/year. For the industry there will often be an uncertainty in the data on the consumption of different similar fuel types. Diesel and similar fuels are used both for heating, in industry and in traffic, and the uncertainties may be high. Normally the export/import of gasoline use across city boundaries may be neglected. This means that vehicles filling within the area and driving outside the area compensate for cars driving into the area from outside. Emission factors. In several recent studies in Indonesia, the emissions from car traffic have been estimated for various areas: * A joint Indonesian German Energy Strategy Study (BPPT/KFA, 1991). In this study, the emissions from 364 different vehicles were measured under different driving conditions, and overall emission factors were extracted, * an air quality study in Medan (Bosch, 1991), * an energy conservation study for Surabaya (IIEC, 1991). The emission factors used in the studies are listed in Table 4. The emission factors used in this URBAIR calculation for Jakarta were selected on the basis of following sources of data: * USEPA emission factors from the AP42 publication. * Emission factors from the WHO publication: "Assessment of Sources of Air, Water and Land Pollution", Part I: Rapid Inventory Techniques in Environmental Pollution (Geneva, 1993). • Emission factors for suspended particles from road vehicles described in Appendix 5. The selected emission factors for road vehicles are shown in Table 5. 110 Appendix 4 Table 4: Emission factors (g/km) for different vehicle classes, used in recent studies in Indonesia Passenger cars Trucks and buses Small trucks and buses Motorcycles Gasoline Diesel diesel Gasoline Diesel Co VWS, 1991 24 5.2 2.5 41 5.3 20/17 (4/2-stroke) Bosch, 1991 57 3.1 8.8 58 24 (MC + Bajaj) IIEC, 1991 -uncontrolled 62 1.9 12 62 1.9 31/26 (4/2-stroke) (Techn. II) - controlled (Techn. IV) 23 1.4 10 23 1.4 22/18 (4/2-stroke) NOx VWS 6.9 1.3 11 9.1 1.5 0.1 5/0.08 (4/2-stroke) Bosch 2.2 1.3 17 2.6 0.18 IIEC 2.0 1.4 20 2.0 1.4 0.2 -Techn. II -Techn. IV 1.0 1.1 13 1.0 1.1 0.4/0.2 (4/2-stroke) HC VWS 2.2 0.5 1.6 3.9 0.5 1.8/9.9 (4/2-stroke) Bosch 8.5 1.3 3.0 9.7 8.9 IIEC -Techn. II 8.3 0.7 3.7 8.3 8.2/19 (4/2-stroke) -Techn. IV 3.0 0.6 1.9 3.0 0.6 3.7 Particles (combustion) VWS 0.36 0.029/0.21 (4/2-stroke) Bosch 0.16 1.2 sox VWS 0.57 0.85 0.014/0.024 (4/2-stroke) Bosch 0.13 0.38 1.75 0.019 Note: VWS factors--overall emission factors, Java driving conditions; Bosch factors--urban driving conditions, Medan; IIEC factors --Uncontrolled vehicles (Techn. II), Controlled vehicles (Techn. IV); Factors for various driving speeds were given. Those presented in thistable are for 24 km/h, i.e. urban driving. Based upon estimates for the total traffic and with emission factors from Table 5, Table 6 shows the emissions of NO, (as NO2) and TSP in Jakarta from different vehicles. Table 5: Emission factors used for URBAIR, Jakarta Spatial distribution of traffic emissions. To evaluate the TSP NOx spatial distribution of the traffic emissions it is necessary to (g/km) (g/km) start with the distribution of the traffic work. This consists of Gasoline traffic on the main roads and local roads. Normally the traffic Passenger cars 0.2 2.7 work on the local roads is in the order of 15-20% of the total. Truck-medium, bus 0.68 8.0 Due to other driving conditions on the local roads than on the Bajaj, MC 0.50 0.07 main roads the emissions, particularly of CO, might be much Diesel higher. Passenger cars 0.6 1.0 Pick-up etc. 0.9 1.0 Truck, bus 2.0 13.0 Bus, Coplet etc. 0.9 13.0 URBAIR-Jakarta 111 Table 6: Emissions of NO. (as NO2) and TSP in Jakarta from different vehicle groups Gasoline AADT 106 car- Emission factor g Emission factor g Emission Emission km/a NOx/km TSPlkm ton/year NOx ton/year TSP Sedan/Taxi 5,659 2.7 0.2 15,279 1132 Pickup 365 2.7 0.33 986 120 Truck, medium 38 8.0 0.68 304 26 Bus, Oplet/Sundaco 183 8.0 0.68 1,464 124 Bajaj 589 0.07 0.5 41 295 MC 4,438 0.07 0.5 311 2219 Sum gasoline 11,272 1.63 0.347 18,385 3916 Diesel AADT 106 car- Emission factorg Emission factorg Emission Emission km/a NO./km TSP/km ton/year NOx ton/year TSP Sedan/Taxi 1,415 1.0 0.6 1,415 849 Pickup 365 1.4 0.9 511 329 Truck, medium 154 13.0 2.0 2,002 308 Truck, heavy 1 13.0 2.0 20 3 Bus, OpleVSundaco 408 13.0 0.9 5,304 367 Bus general 301 13.0 2.0 3,913 602 Sum diesel 2,644 4.98 0.93 13,165 2458 Total 13,916 2.267 0.35 31,550 4866 Main road network and local roads. From Jakarta maps a main road network was defined. At the beginning this was a coarse network, but as the work proceeded the network was gradually made finer. The coordinates for all crossings in this network were measured and transformed to the grid net. Figure 3 shows the main road network used in Jakarta. We had traffic data only for a few major roads, so we had to use the data very extensively. From other reports from Jakarta there seems to exist more data, but these have not been available in this work. 112 Appendix 4 Figure 3: Main road network in Jakarta Main Roads Jakar'ta (75. 295) From a road map for Jakarta (FALK-plan: Street atlas and index, 1992) the main roads were grouped into four classes, based upon the map's representation of the roads, and these were later subdivided according to other maps. Finally the groups were given values for AADT from 140,000 to about 20,000. From this road network the total road length and the traffic work were calculated within each grid. This gave a total of 569 km roads and 38.5 mill. car-km/day (14xlO9 car-km/yr). By this method we got an overestimate of the traffic work. The calculated traffic work on the main road network only gave about the same value as for the total traffic work (incl. local roads) which was calculated on the basis of the data for total and specific fuel consumption, and vehicle composition. The traffic data for the road network was therefore reduced, except for roads near places with counts, where the counts were still used. In this way the estimate of the traffic work on the main roads was reduced to about lOx lO9 car-km/yr, some 70% of the total traffic URBAIR-Jakarta 113 activity. The rest of the traffic, traffic on local roads, estimated to about 4x1O9 car-km/yr, was distributed according to the population distribution. This is probably not correct since much of the population in the densest populated areas does not own motor vehicles. When more accurate data for the traffic on the main road net is available, the spatial distribution of the traffic and the traffic emissions can be calculated more correctly. Figure 4 shows a map of the total traffic work for Jakarta, and figures 5 and 6 show the emissions of NOx and TSP from car traffic in Jakarta. Figure 4: Traffic work in Jakarta MAP OF TRAFFIC UNIT : CAR-KM/Y SOURCE POP PERIOD 1990 PLACE: JAK GRID SIZE: 1500 METER CREATED: 1995/07/28 17.41 MAXIMUM VALUE IS 2.9004E+08, IN (11,16) SUM= 1.71176E+10 SCALE FACTOR: 1.OE+05 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 J=20 31. 112. 31. 165. 15. 0. 0. 0. 0. O. 0. 0. 0. 0. 418. 808. 386. 127. 73. 6. J=19 38. 47. 23. 85. 181. 174. 240. 241. 143. 130. 16. 396. 459. 725. 189. 615. 170. 64. 82. 9. J=18 63. 105. 102. 101. 52. 120. 277. 667.1298. 775. 544. 689. 321. 475. 809.1245. 392. 214. 67. 30. J=17 70. 272. 316: 387. 492. 332. 559. 550. 950. 866.1168. 962. 722. 702. 908. 841. 345. 301. 41. 419. J=16 281. 96. 86. 164. 143. 287.1116.1170.1354.1690.2900.1555. 364. 340.1206. 202. 38. 38. 360. 102. J=15 70. 108. 114. 248. 150. 386. 927.1128.1742. 727.2584.2286.1068. 546. 680. 531. 590. 436. 755. 290. J=14 93. 183. 212. 337. 662. 762.1226.1270.1411.1050.1860.1810.1371. 908.1192. 762. 766. 45. 35. 230. J=13 119. 92. 51. 48. 48. 186. 660.1235.1596.1556.1479.1182.1172. 872. 939. 946. 677. 126. 103. 96. J=12 100. 310. 123. 247. 176. 319. 409.1382.1067.2099.1175.1660.1403.1987.1460. 699. 996. 594. 478. 50. J=11 0. 11. 366. 403. 442. 571. 511. 942.1608.1313.1737.1131.1212.1073. 942. 646. 416. 479. 166. 0. 3=10 0. 0. 0. 0. 151. 283. 287. 878.1662.1133.1667.1799.1430.1688.1944.1188.1255. 557. 162. 81. J. 9 0. 0. 0. 0. 77. 285. 455. 786. 919. 841. 984. 964. 943.1301. 845. 460. 741. 671. 552. 636. J. 8 0. 0. 0. 0. 28. 348. 485. 676. 786. 568.1164. 314. 828. 794. 634. 30. 80. 317. 194. 97. J3 7 0. 0. 0. 0. 46. 196. 661. 572. 831. 651. 991. 655. 278. 513.1028. 348. 308. 248. 0. 0. J3 6 0. 0. 0. 0. 0. 324. 310. 298. 368. 197. 350. 798. 325. 603. 750. 62. 16. 0. 0. 0. J- 5 0. 0. 0. 0. 0. 127. 72. 164. 249. 191. 204. 503. 336. 611. 436. 584. 196. 164. 82. 0. J3 4 0. 0. 0. 0. 0. 0. 0. 86. 25. 79. 152. 538. 248. 214. 81. 617. 32. 0. 0. 0. J= 3 0. 0. 0. 0. 0. 0. 10. 55. 44. 89. 77. 434. 130. 292. 158. 619. 12. 0. 0. 0. J3 2 0. 0. 0. 0. 0. 0. 0. 9. 54. 63. 56. 164. 86. 170. 58. 614. 11. 0. 0. 0. J3 1 0. 0. 0. 0. 0. 0. 0. 6. 40. 25. 0. 0. 0. 30. 65. 431. 7. 0. 0. 0. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 114 Appendix 4 Figure 5: Emission of NO.from car traffic in Jakarta MAP OF NOx traf UNIT : kg/h SOURCE Traffic PERIOD 1990 PLACE: JAK GRID SIZE: 1500 METER CREATED: 1995/07/28 17.41 MAXIMUM VALUE IS 7.5062E+01, IN (11,16) SUM= 4.43003E+03 SCALE FACTOR: 1.0E-02 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 J=20 80. 290. 81. 427. 39, .1082.2091. 999. 329. 190. 14. J=19 100, 121. 59. 220. 468. 449. 621. 624. 370. 336. 42.1025.1188.1877. 490.1591. 440. 165. 213. 23. J=18 163, 272. 264. 260. 134. 312. 718.1725.3358.2006.1408.1784. 830.1229.2094.3223.1015. 553. 173, 78. J=17 180. 705. 819.1001.1273. 860.1447.1423.2459.2241.3022.2490.1867.1817.2350.2178. 894. 780. 105.1085. J=16 727. 248. 222. 424. 371. 744.2888.3028.3503.4375.7506.4023. 942. 880.3122. 522. 100. 100. 933. 265. J=15 182. 281. 295. 641. 388.1000.2400.2919.4507.1881.6686.5917.2765.1414.1759.1374.1528.1129.1953. 750. J=14 241. 475. 550. 873.1713.1971.3174.3286.3652.2718.4815.4684.3549.2351.3085.1971.1981. 116. 90. 595. 3=13 308. 238. 131. 123. 123. 481.1709.3195.4131.4026.3826.3060.3033.2256.2429.2447.1753. 325. 266. 248. J=12 259. 802. 318. 640. 456. 826.1058.3578.2762.5433.3041.4297.3632.5142.3778.1809.2579.1538.1238. 128. J=ll 28. 947.1043.1144.1477.1322.2438.4161.3398.4496.2928.3137.2777.2438.1672.1077.1240. 431. J=10 . . 392. 733. 743.2273.4301.2931.4314.4655.3700.4369.5030.3075.3248.1442. 419. 210. J= 9 . , 200. 739.1177.2034.2378.2176.2547.2495.2439.3366.2186.1190.1917.1737.1429.1646. J= 8 . . 73. 901.1256.1748.2035.1470.3012. 812.2142.2055.1640. 78. 207. 820. 502. 251. J= 7 . . 119. 507.1712.1481.2149.1684.2565.1695. 720.1328.2661. 901. 797. 642. J= 6 838. 802. 771. 952. 511. 907.2066. 840.1560.1940. 159. 41. J= 5 329. 186. 425. 645. 494. 529.1303. 870.1582.1129.1512. 506. 424. 212. J= 4 222. 64. 205. 395.1393. 643. 553. 209.1598. 82. J= 3 26. 142. 113. 231. 199.1123. 336. 755. 410.1603. 31. J= 2 .. . 24. 140. 163. 144. 424. 223. 439. 149.1589. 28. J= 1 ,. .. . .14. 104. 64. . . . 77. 168.1117. 18. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 URBAIR-Jakarta 115 Figure 6: Emission of TSP from car traffic in Jakarta MAP OF TSP traf UNIT: kg/h SOURCE : Traffic PERIOD : 1990 PLACE: JAK GRID SIZE: 1500 METER CREATED: 1995/07/28 17.41 MAXIMUM VALUE IS 1.2835E+02, IN (11,16) SUM= 7.57521E+03 SCALE FACTOR: 1.OE-01 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 J=20 14. 50. 14. 73. 7. . . . . . . . . 185. 358. 171. 56. 32. 2. J=19 17. 21. 10. 38. 80. 77. 106. 107. 63. 58. 7. 175. 203. 321. 84. 272. 75. 28. 36. 4. J=18 28. 47. 45. 44. 23. 53. 123. 295. 574. 343. 241. 305. 142. 210. 358. 551. 174. 95. 30. 13. J=17 31. 121. 140. 171. 218 147. 247. 243. 420. 383. 517. 426. 319. 311. 402. 372. 153. 133. 18. 185. J=16 124. 42. 38. 72. 63. 127. 494. 518. 599. 748.1284. 688. 161. 151. 534. 89. 17. 17. 160. 45.. J=15 31. 48. 50. 110. 66. 171. 410. 499. 771. 322.1143.1012. 473. 242. 301. 235. 261. 193. 334. 128. J=14 41. 81. 94. 149. 293. 337. 543. 562. 624. 465. 823. 801. 607. 402. 528. 337. 339. 20. 15. 102. J=13 53. 41. 22. 21. 21. 82. 292. 546. 706. 689. 654. 523. 519. 386. 415. 418. 300. 56. 46. 42. .=12 44. 137. 54. 109. 78. 141. 181. 612. 472. 929. 520. 735. 621. 879. 646. 309. 441. 263. 212. 22. J=1l . 5. 162. 178. 196. 253. 226. 417. 711. 581. 769. 501. 536. 475. 417. 286. 184. 212. 74. J=10 . 67. 125. 127. 389. 735. 501. 738. 796. 633. 747. 860. 526. 555. 247. 72. 36. J= 9 . 34. 126. 201. 348. 407. 372. 436. 427. 417. 576. 374. 204. 328. 297. 244. 281. J= 8 . 13. 154. 215. 299, 348. 251. 515. 139. 366. 351. 281. 13. 35. 140. 86. 43. a= 7 . 20. 87. 293. 253. 368. 288. 439. 290. 123. 227. 455. 154. 136. 110. J= 6 143. 137. 132. 163. 87. 155. 353. 144. 267. 332. 27. 7. J= 5 56. 32. 73. 110. 84. 90. 223. 149. 271. 193. 258. 87. 73. 36. J= 4 38. 11. 35. 67. 238. 110. 95. 36. 273. 14. J= 3 4. 24. 19. 40. 34. 192. 57. 129. 70. 274. 5. J= 2 4. 24. 28. 25. 73. 38. 75. 25. 272. 5. J= 1 2. 18. 11. . . . 13. 29. 191. 3. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 In the calculations of the traffic work we had no specific information about the traffic composition on each road, or variations in the traffic composition in various parts of Jakarta. This means that for calculating the emission field for traffic we had to make use of the average, weighed emission factors from Table 5, 2.27 gNO"/km and 0.45 gTSP/km. This gives traffic emission fields for NO, and TSP shown in figures 5 and 6. EMISSIONS FROM INDUSTRY Industrial emissions will normally consist of process emissions and emissions from combustion of fossil fuels. To have a good emission survey it is necessary to collect data about consumption, production and emitting conditions. It is desirable to estimate the emissions from measurements, and this is done in many cases. The results of such measurements are used to develop emission factors, for example, from the combustion of one ton of coal or from production of one ton of steel. Emission factors will only give average estimates; individual analyses are required for accurate values. 116 Appendix 4 In this study we have no information available about Table 7: Emissionfactors for industry individual industrial activities Number of Employment Mg TSP* kg TSP per in Jakarta. Bosch has estimated establishments per est. employee emissions of TSP for different Food and tobacco 129 21,765 10 59 industries in Medan at Textiles 32 2,866 25 279 Wood and furniture 50 4,972 25 251 Sumatra, as shown in Table 7 Paper, Printing 40 2,849 25 351 for TSP. Non-metallic 100 12,556 25 199 The industrial emission of minerals TSP for Jakarta are estimated Basic metals 23 1,424 50 808 by using statistical data for Metal works 4 1,081 50 185 Jakarta combined with Bosch's Chemicals, Oil 94 8,866 10 106 data. Table 8 shows the Plastics Average estimates only; individual analyses are required for accurate values. number of medium and large Source: Bosch (1991). establishments, the number of workers and estimated emission of TSP for 1989, separated into 9 classes of industry. Table 8: Industrial emission of TSP Number of Workers Factor Emissions establishments kg/yr employee tons/year Food, beverage and tobacco 222 14,724 59 869 Textiles 717 87,620 279 24,446* Wood and wood prod. 131 9,250 251 2,322 Paper and paper prod. 193 14,684 351 5,154 Industrial chemicals 380 36,022 106 3,818* Non-metallic mineral products 38 8,884 199 1,768 Iron and steel basic industry 17 2,796 808 2,259** Mineral products, machines and equipment 361 54,471 185 10,077 Other 41 3,745 Total 2,100 232,196 50,713 * appears too high appears much too low, considering data from Cowiconsult. According to Table 8, 2,100 medium and large enterprises employ more than 200,000 production workers. Each of these enterprises employing more than 100 production workers emits an average Table 9: TSP emission from industrialprocesses in of 25 tons TSP/year. Jakarta (tons/year) Considering the two last groups Number of TSP emission in Table 8 (except "other"), 378 establishments tons/year medium and large enterprises Food, beverage, tobacco and textiles 939 9,400 employing more than 57,000 Wood and wood prod. 131 2,300 production workers, it is assumed Paper and paper prod. 193 5,200 that each enterprise emits an average Industrial chemicals 380 3,800 of 30 tons TSP!year. Based upon Non-metallic mineral products 38 1,700 these assumptins T eab 9 Base pows Iron, steel, mineral products etc. 378 9,500 these assumptions Table 9 shows Sum 31,900 URBAIR-Jakarta 117 average emissions from industrial processes in Jakarta. Large differences are expected to be found between individual factories, and information about location and emissions from polluting factories is needed before air quality guidelines are enforced. Referring to the list of 100 industries which may qualify for assistance (World Bank, 1992) a number of industries in Jakarta emitting (2-8)x 106 kg TSP per year are identified and the cost of pollution abatement is estimated. Spatial distribution of industrial emissions. As already mentioned we have had no information about the location of the industries in Jakarta, so we had to use an unorthodox method: From two different maps of Jakarta with symbols of industries we have counted the number of industrial symbols within each grid, with a total of 207 "industry" symbols, and the emissions are distributed according to this. Figure 7 shows the distribution of industry symbols. The total emission of NO, from industrial processes is estimated to 1,784 tons/year, and the "industry" file is multiplied by 0.9838 to give an average NO, emission field as shown in Figure 8. From Figure 1 in Appendix 7 the emission of TSP from industrial processes and fuel combustion are estimated to 32,068 tons/year. When the "industry" file is multiplied by 17.685 we get an average TSP emission field as shown in Figure 9. EMISSIONS FROM FUEL COMBUSTION IN SMALL INDUSTRIES/DOMESTIC ACTIVITIES From Figure 2 in Appendix 7 the NO, emission from fuel combustion in homes/small industry are estimated to 8,176 tons NO, per year. This is distributed according to the population distribution, and the population file is multiplied by 1.313E-4 to give an average NOx emission field as shown in Figure 10. From Figure 1 in Appendix 7, the TSP emission is estimated to be 10,536 tons per year, and the population file is multiplied by 1.660E-4 to give an average TSP emission field as shown in Figure 11. *. ~~00 Lb 0~~~~~1 . . . . . . . . H - t z 14wIBuXC/oOP H) H^ H .> ej O bH %3 , KY > AL~~~~~~~~~~ H -t H . . . . . . . . . . . . . . . . . . o , . 0 . . . . . . . . . . . . . . . . . . . . U . £i > . . . . . . . . . . . . . . . . oH .-.4. . . . . . . . - ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ 0 .4~~~ ~~~~~~~ . .4 . . H LA N 0~~~~~~ .4 01 H H z H} t URBAIR-Jakarta 119 Figure 8: Average industrial emission of NO. in Jakarta (0.01 kg NO/h) MAP OF: NOx IND UNIT: KG/H SOURCE Industry PERIOD : 1990 PLACE: Jakarta GRID SIZE: 1500 METER CREATED: 1995/09/27 12.15 MAXIMUM VALUE IS 1.1812E+01, IN (18,14) SUM= 2.03653E+02 SCALE FACTOR: -1.0E-02 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 J=20 . . . . . . . . . . . . . . . 98. . . 295. 98. J=19 . 98. 98. ... . . . . . 689. 492. 98 394. J=18.. . . . 9. 197. . 295. . . 295. . .394. 98. 197. 98. J=17 98. 98. 197. 98. 197..295. 394. J.16 197. . 197. 295. 197. . . . . . . . 295 98. . 492. 98. J=15 . 98. 98. .98. 295. 197. 197. 492. 394. 295. J=14 .. . . . . . . . . 197. 295. 492. 590.1181. 885. 787. J=13 98. 197. 295. 492. 689. 787. 394. 197. J=12 98. 295. 295. 295. J=11 3=10 .= 9 98. 3J.. 197. 98. J. 3.197. 98. J= 2 295. 394. 3= 1 197. 197. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 120 Appendix 4 Figure 9. Average industrial emission of TSP in Jakarta (0.1 kg TSP/h) MAP OF: TSP IND UNIT: KG/H SOURCE Industry PERIOD 1990 PLACE: Jakarta GRID SIZE: 1500 METER CREATED: 1995/09/27 12.15 MAXIMUM VALUE IS 2.1865E+02, IN (18,14) SUM= 3.77009E+03 SCALE FACTOR: 1.0E-01 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 J520 . . . . . . . . . . . . . . . 182. . . 546. 182. J=19 . . 182. 182. 1275. 911. 182. 729. J=18 . . . 182. 364. 546. . . .546. . 729. 182. 364. 182. J17.... 182. .182.. 364. 182 . . 364. 546. 729. J=16 364. . 364. 546. 364. . . . . . 546. 182. . 911. 182. J=15 . . 182. 182. .. . . 182. 546. 364. 364. 911. 729. 546. J=14 .. . . . . . . 364. 546. 911.1093.2186.1639.1457. J-13... . . 182. 364. 546. 911.1275.1457. 729. 364. J.12 .. . . . . . . 182. 546. 546. 546. J=11 J.10 Js9 , , , : . ,,. .9. . . 182. 3= 8 J.a je 7 J. 6 . . . . . . . . .364. . . .182. J- S 5 546. J= 4 364. 182. J- 3 364. 182. J= 2 546. 729. J= 1 364. 364. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 18 20 URBAIR-Jakarta 121 Figure 10: No. emission from domestic activities/small industry in Jakarta (0.01 kg TSP/h) MAP OF : NOX DOM UNIT : KG/H SOURCE : DOMESTIC PERIOD : 1990 PLACE: JAK GRID SIZE: 1500 METER CREATED: 1995/07/28 17.41 MAXIMUM VALUE IS 1.5807E+01, IN (11,15) SUM= 9.33326E+02 SCALE FACTOR: 1.OE-02 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 J.20 0. 0. 1. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 4. 8. J-19 51. 62. 30. 7. 3. S. 0. 0. 0. 0. 0. 0. 0. 100. 213. 83. 227. 83. 54. 12. J318 84. 140. 137. 42. 9. 51. 206. 335. 335. 0. 0. 256. 182. 559.1079. 884. 523. 285. 37. 13. J=17 67. 95. 154. 171. 123. 29. 161. 733. 693. 709. 512. 131. 515. 647.1014. 365. 461. 402. 55. 32. J=16 102. 127. 114. 139. 190. 265. 616. 603.1037.1179.1372. 521. 193. 193. 1i2. 180. 51. 51. 51. 38. J515 95. 144. 152. 121. 121. 467. 834. 948. 742. 519.1581.1123. 834. 415. 160. 173. 85. 56. 49. 34. J=14 56. 138. 110. 91. 146. 253. 486.1087. 855. 299.1067.1175. 838. 467. 261. 198. 126. 59. 46. 118. J=13 0. 0. 46. 64. 64. 248. 486.1021. 958.1442. 642. 638. 655. 835. 515. 303. 331. 167. 137. 127. J=12 0. 0. 53. 249. 147. 295. 298.1279. 995.1002. 768.1241.1136. 930. 683. 255. 203. 106. 106. 49. J=11 0. 0. 77. 127. 152. 328. 341. 457. 742. 957. 895.1008.1225. 895. 504. 448. 448. 427. 222. 0. J=10 0. 0. 0. 0. 169. 345. 382. 411. 534. 524.1166.1133.1103. 933. 469. 352. 277. 274. 0. 0. J= 9 0. 0. 0. 0. 104. 315. 391. 584. 528. 182. 731. 593. 692. 674. 87. 230. 201. 147. 0. 0. J= 8 0. 0. 0. 0. 38. 398. 209. 499. 520. 155. 882. 419. 558. 484. 87. 41. 0. 0. 0. 0. J- 7 0. 0. 0. 0. 62. 261. 169. 268. 337. 332. 411. 273. 299. 352. 81. 68. 0. 0. 0. 0. J= 6 0. 0. 0. 0. 0. 108. 161. 339. 280. 263. 299. 399. 335: 357. 232. 83. 21. 0. 0. 0. J= 5 0, 0. 0. 0. 0. 0. 96. 138. 147. 189. 247. 272. 377. 238. 215. 100. 42. 0. 0. 0. J3 4 0. 0. 0. 0. 0. 0. 0. 30. 33. 88. 203. 311. 331. 64. 108. 79. 42. 0. 0. 0. J= 3 0. 0. 0. 0. 0. 0. 0. 0. 58. 119. 102. 180. 173. 123. 72. 42. 16. 0. 0. 0. J= 2 0. 0. 0. 0. 0. 0. 0. 13. 72. 84. 74. 0. 116. 117. 76. 43. 14. 0. 0. 0. J= 1 0. 0. 0. 0. 0. 0. 0. 8. 54. 33. 0. 0. 0. 39. 87. 26. 9. 0. 0. 0. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 122 Appendix 4 Figure 11: TSP emissionfrom domestic activities/small industry in Jakarta (0.01 kg/TSP/h) MAP OF: TSP DOM UNIT KG/H SOURCE DOMESTIC PERIOD 1990 PLACE: JAR GRID SIZE: 1500 METER CREATED: 1995/07/28 17.41 MAXIMUM VALUE IS 1.9985E+01, IN (11,15) SUM= 1.17999E+03 SCALE FACTOR: 1.OE-02 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 J=20 0. 0. 2. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 5. 10. J=19 65. 78. 38. 8. 3. 7. 0. 0. 0. 0. 0. 0. 0. 126. 269. 105. 287. 105. 68. 15. J=18 106: 178. 173. 53. 12. 65. 261. 423. 423. 0. 0. 324. 231. 707.1364.1117. 661. 360. 46. 17. J=17 85. 120. 194. 216. 156. 37. 204. 926. 876. 896. 647. 166. 651. 818.1281. 461. 583. 508. 70. 40. J=16 129. 161. 144. 176. 241. 335. 778. 762.1311.1491.1735. 659. 244. 244. 217. 227. 65. 65. 65. 48. J=15 120. 183. 193. 153. 153. 591.1054.1198. 938. 656.1998.1419.1054. 525. 203. 219. 108. 71. 61. 43. J=14 71. 174. 139. 115. 184. 320. 614.1374.1081. 378.1349.1486.1059. 591. 330. 251. 159. 75. 58. 149. J=13 0. 0. 58. 81. 81. 314. 614.1291.1212.1823. 812. 807. 828.1056. 651. 383. 418. 211. 173. 161. J=12 0. 0. 66. 315. 186. 373. 377.1617.1258.1266. 971.1569.1436.1175. 863. 322. 257. 134. 134. 61. J=11 0. 0. 98. 161. 193. 415. 432. 578. 938.1210.1132.1275.1549.1132. 637. 566. 566. 539. 281. 0. J=10 0. 0. 0. 0. 214. 437. 483. 520. 676. 662.1474.1432.1394.1180. 593. 445. 350. 347. 0. 0. J= 9 0. 0. 0. 0. 131. 398. 495. 739. 667. 231. 925. 750. 875. 852. 110. 290. 254. 186. 0. 0. J= 8 0. 0. 0. 0. 48. 503. 264. 631. 657. 196.1115. 529. 705. 612. 110. 51. 0. 0. 0. 0. J= 7 0. 0. 0. 0. 78. 330. 214. 339. 427. 420. 520. 345. 378. 445. 103. 86. 0. 0. 0. 0. J= 6 0. 0. 0. 0. 0. 136. 204. 428. 354. 332. 378. 505. 423. 451. 294. 105. 27. 0. 0. 0. J= 5 0. 0. 0. 0. 0. 0. 121. 174. 186. 239. 312. 344. 476. 300. 272. 126. 53. 0. 0. 0. J= 4 0. 0. 0. 0. 0. 0. 0. 38. 41. 111. 257. 393. 418. 81. 136. 100. 53. 0. 0. 0. 3= 3 0. 0. 0. 0. 0. 0. 0. 0. 73. 151. 129. 227. 219. 156. 91. 53. 20. 0. 0. 0. J= 2 0. 0. 0. 0. 0. 0. 0. 17. 91. 106. 93. 0. 146. 148. 96. 55. 18. 0. 0. 0. J= 1 0. 0. 0. 0. 0. 0. 0. 10. 68. 41. 0. 0. 0. 50. 110. 33. 12. 0. 0. 0. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 26 17 18 19 20 REFERENCES Bachrun, R.K., H. M. Samudro, M. Soedomo, and B. Tjasjono. 1991. "LLAJR Air Pollution Monitoring and Control Project." Draft Interim Report, Institute Technology Bandung. Badan Pengkajian dan Penerapan Teknologi (BPPT)/Forschungzentrum Julich GmbH (KFA). 1991. "Environmental Impacts of Energy strategies for Indonesia: Emission Modeling Aspects and Emission Coefficients of the Traffic Sector." BPPT, Jakarta/Forschungszentrum Juilich, Jilich. Bosch, J. 1991. "Air Quality Assessment in Medan. Second Medan Urban Development Project." Medan. International Institute for Energy Conservation (IIEC). 1991. "Assessment of Transportation Growth in Asia and its Effects on Energy Usage, Environment and Traffic Congestion: Case Study Surabaya, Indonesia." PT Mojopahit Konsultama. Jakarta. Jakarta Statistical Office (JSO). 1991. Jakarta in figures. Jakarta. URBAIR-Jakarta 123 Soedomo, M. 1993. "Urban Air Quality Management in Asia (URBAIR) Development of an Action Plan for Jakarta." Draft Final Report. Institute Technology, Bandung. World Bank. 1992. Indonesia: Industrial Efficiency and Pollution Abatement (EEPA) project. List of major industries which qualify for assistance. Washington, D.C. I APPENDIX 5: EMISSION FACTORS, PARTICLES INTRODUCTION Emission factors (emitted amount of pollutant per quantity of combusted fuel, or per km driven, or per produced unit of product) are important input data to emissions inventories, which again are essential input to dispersion modelling. The knowledge of emission factors representative for the present technology level of Asian cities is limited. For the purpose of selecting emission factors for the URBAIR study, references on emission factors were collected from the open literature and from studies and reports from cities in Asia. This appendix gives a brief background for the selection of emission factors for particles used in the air quality assessment part of URBAIR. MOTOR VEHICLES The selection of emission factors for motor vehicles for use in the URBAIR project to produce emissions inventories for South-East Asian cities, was based on the following references: * WHO (1993), * USEPA (EPA AP42 report series) (1985), * Vehicles Emission Control Project (VECP), Manila (Baker, 1993), * Indonesia (Bosch, 1991), * Williams et al. (1989), * Motorcycle emissions standard and emissions control technology (Weaver and Chan, 1993). Table 1 gives a summary of emission factors from these references for various vehicle classes. From these, the emission factors given in Table 2 were selected, for use as a basis for URBAIR cities. Taking into account the typical vehicle/traffic activity composition, the following vehicle classes give the largest contributions to the total exhaust particle emissions from traffic: * Heavy duty diesel trucks, * Diesel buses, * Utility trucks, diesel, * 2-stroke 2- and 3-wheelers. 125 126 Appendix 5 Thus, the emission factors for these vehicle classes are the most important ones. Table 1: Emissionfactors (glkm)for particle emissions from motor vehicles Comments. It is clear that there is not a very Fuel and Vehicle Particlesg/km Reference solid basis in actual measurements on which to Gasoline estimate particle emission factors for vehicles in Passenger cars 0.33 USEPA/WHO South-East Asian cities. The given references 0.10 VECP, Manila represent the best available basis. Comments are 0. 6 Indonesia (Bosch) given below for each of the vehicle classes. Trucks, utility 0.12 VECP, Manila 0.33 USEPA Gasoline: USEPA * Passenger cars: Fairly new, normally well Trucks, heavy duty 0.33 USEPA maintained cars, engine size less than 2.5 1, 3-wheelers, 2 stroke 0.21 USEPA/WHO without 3-way catalyst, running on leaded 2.00/ VECP, Manila gasoline (0.2-0.3 g Pb/I), have an emission 0.21/0.029 Indonesia VWS factor of the order of 0.1 g/km. Older, poorly 0.28/0.08 Weaver and Chan maintained vehicles may have much larger Diesel emissions. The USEPA/WHO factor of 0.33 Car, taxi 0.6 VECP, Manila g/km can be used as an estimate for such 0.45 USEPA/WHO vehclkmcaes used as an estimate for such 0.37 Williams vehicles. Trucks, utility 0.9 VECP, Manila - Utility trucks: Although the VECP study 0.93 EPA (Manila) uses 0.12 g/km, the EPA factor of Trucks, heavy/bus 0.75 WHO 0.33 g/km was selected for such vehicles, 1.5 VECP, Manila taking into account generally poor 0.93 USEPA maintenance in South-East Asian cities. 1.2 Bosch - Heavy duty trucks: Only the USEPA have 2.1 Williams Note: Relevant as a basis for selection of factors to be given an estimate for such vehicles, 0.33 used in South-East Asian cities. g/km, the same as for passenger cars and utility trucks. c 3-wheelers, 2 stroke: The USEPA and WHO Table 2: Selected emission factors (g/km) for particks from road vehicles suggest 0.2 g/km for such vehicles. used in URBAIR * Motorcycles, 2 stroke: The Weaver report supports Vehicles class Gasoline Diesel the 0.21 g/km emission factor suggested by Passengercars/taxies 0.20 0.6 USEPA/WHO. In the VECP Manila study a factor Utility vehicles/light trucks 0.33 0.9 of 2 g/km is suggested. This is the same factor as Motorcycles/tricycles 0.50 for heavy duty diesel trucks, which seems much Trucks/buses 2.0 too high. Visible smoke emissions from 2-stroke 2- and 3-wheelers is normal in South-East Asian cities. Low-quality oil as well as worn and poorly maintained engines probably both contribute to the large emissions. The database for selecting a representative emission factor is small. In the data of Weaver and Chan (1993), the highest emission factor is about 0.55 g/km. For URBAIR, we choose a factor of 0.5 g/km. Realizing that this is considerably higher than the factor suggested by USEPA, we also take into consideration the factor 2 g/km used in the VECP study in Manila, which indicates evidence for very large emissions from such vehicles. URBAIR-Jakarta 127 * Motorcycles, 4-stroke: The emission factor is much less than for 2-stroke engines. The Weaver report gives 0.08 g/km, while 0.029 g/km is given by the VWS study in Indonesia (Bosch, 1991). Diesel: * Passenger cars, taxis: The factor of 0.6 g/km given by the VECP Manila is chosen, since it is based on measurements of smoke emission from vehicles in traffic in Manila. The 0.45 g/km of USEPA/WHO was taken to represent typically maintained vehicles in Western Europe and the United States, as also measured by Larssen and Heintzenberg (1983) on Norwegian vehicles. This is supported by Williams' factor of 0.37 g/km for Australian vehicles. * Utility trucks: The USEPA and the VECP Manila study give similar emission factors, about 0.9 g/km. * Heavy duty trucks/buses: The factors in the table range from 0.75 glkm to 2.1 g/km. It is clear that "smoking" diesel trucks and buses may have emission factors even much larger than 2 g/km. In the COPERT emission database of the European Union factors as large as 3-5 g/km are used for "dirty" city buses. Likewise, based on relationships between smoke meter reading (e.g. Hartridge smoke units, HSU) and mass emissions, it can be estimated that a diesel truck with a smoke meter reading of 85 HSU, as measured typically on Kathmandu trucks and buses (Rajbahak and Joshi, 1993), corresponds to an emission factor of roughly 8 g/km! As opposed to this, well maintained heavy duty diesel trucks and buses have an emission factor of 0.7-1 g/km. As a basis for emission calculations for South-East Asian cities we choose an emission factor of 2 g/km. This corresponds to some 20% of the diesel trucks and buses being "smoke belchers". A larger fraction of "smoke belchers", such as Table 3: Emission factors for oil combustion in Kathmandu, will result in a larger (kg/m3) emission factor. Emission factor Uncontrolled Controlled Utility boilers Residual oila) Grade 6 1 .25(S)+0.38 xO.008 (ESP) FUEL COMBUSTION Grade 5 1.25 x0.06 (scrubber) Grade 4 0,88 xO.2 (multicyclone) Oil. The particle emission factors IndustriaVcommercial boilers suggested by USEPA (AP 42) are taken as Residual oil (as above) xO.2 (multicyclone) a basis for calculating emissions from Distillate oil 0.24 combustion of oil in South-East Asian Residential fumaces cities. The factors are given in Table 3. S: Sulfur content in % by weight a): Another algorithm for calculating the emission factors is as follows: 7,3xA kg/m3, where A is the ash content of the oil. Source: USEPA, AP 42. REFERENCES Baker, J., R. Santiage, T. Villareal, and M. Walsh. 1993. "Vehicular emission control in Metro Manila." Asian Development Bank (PPTA 1723). Manila. 128 Appendix 5 Bosch, J. 1991. "Air quality assessment in Medan." Extract from Medan Urban Transportation Study. The World Bank. Washington D.C. Economopoulos, A. P. 1993. "Assessment of Sources of Air, Water, and Land Pollution: A Guide to Rapid Source Inventory Techniques and Their Use in Formulating Environmental Control Strategies. Part One: Rapid Inventory Techniques in Environmental Pollution." (WHO/PEP/GETNET/93.1 -A). World Health Organization. Geneva. Larssen, S. and J. Heintzenberg. 1983. "Measurements of Emissions of Soot and Other Particles from Light-duty Vehicles." (NILU OR 50/83). (In Norwegian.) Lillestr0m, Norway. Rajbahak, H.L. and K. M. Joshi. 1993. "Kathmandu Valley Vehicular Transportation and Emission Problems." Metropolitan Environment Improvement Program. Urban Air Quality Management Workshop (URBAIR), December 2, 1993. Jakarta. United States Environmental Protection Agency. 1985. "Compilation of Air Pollutant Emission Factors." 4th edition. AP-42. Research Triangle Park, NC. Weaver, C.S. and L.-M. Chan. 1993. "Motorcycle Emission Standards and Emission Control Technology." Engine, Fuel, and Emissions Engineering, Inc. Sacramento, CA. Williams, D.J., J. W. Milne, D. B. Roberts, and M.C. Kimberlee. 1989. "Particulate Emissions from 'In-use' Motor Vehicles: Part I. Spark ignition vehicles." Atmospheric Environment 23, 2639-2645. Williams, D.J., J. W. Milne, S. M. Quigley, D. B. Roberts, and M. C. Kimberlee. 1989. "Particulate Emissions from 'In-use' Motor Vehicles: Part II. Diesel Vehicles. Atmospheric Environment, 23, 2647-2662. APPENDIX 6: POPULATION EXPOSURE CALCULATIONS METHODOLOGY Data for population exposure in Jakarta are estimated for annual average TSP-values. The measured values specify the pollution level at the measuring stations. Dispersion calculations are used to specify the spatial distribution of concentration values over the urban area. The dispersion calculations are based on data for wind, dispersion conditions and for emission distribution over the city. The input data for dispersion calculations should be improved in the future regarding the following points: * Emission from industry including emissions from the power plant should be measured and emission conditions are important for the local air quality. * Emissions due to resuspension and due to refuse burning (Bosch, 1991) should be controlled by measurements in Jakarta. * The relationship between emission conditions and measured concentration values in the northern part of Jakarta should be clarified. * The data on dispersion conditions should be improved and a wind model accounting for coastal effects may be important for discussing effects of emission reductions in air pollution episodes. To give a first estimate for considering cost/effect relationships only annual average concentrations were considered. To specify the annual urban scale pollution level, average concentration in grid squares covering 1.5 x 1.5 km2 was calculated. The following groups of sources were considered: * car traffic including resuspension, * fuel combustion including refuse burning, * industrial processes, and * miscellaneous, including airports, harbor and construction. The spatial population distribution is calculated by establishing the number of inhabitants in each subdistrict (Kelurahan). A distribution key was estimated to transform the data on population in "kelurahans" to data on population in the grid system. To develop the distribution key a detailed map of Jakarta was used (Peta Rupabumir Indonesia, 1990 1:25 000) to take into account the 129 130 Appendix 7 location of residential areas. To take account of polluted areas along roads with high traffic intensities the locations of the main roads were specified as shown in Figure 1. Figure l:The network of main roads The length of main roads in each grid square is determined and an additional concentration is estimated for people living in 30 m zones on each side of the road starting from a distance of 10 m from the edge of the road. The population density in this zone is assumed to be equal to the average density in the grid square. We have not taken into account double exposure from crossing roads. The distribution of population exposure is calculated by counting the number of people living in each grid square and the number of people living along roads in each grid square separately, considering the respective concentration levels. The calculated concentration in each grid square consists of contributions from four source groups: * car traffic, * industry and commercial, * domestic, and * extra-urban background concentration. URBAIR-Jakarta 131 Each of the contributions is calculated separately, and a source reduction influences the respective contribution proportionally to the amount of the source reduction in question. The effect on the exposure curve of the source reductions is calculated for a 25 and 50 percent source reduction for each group. Calculation of exposure to air pollution in Jakarta. Table I shows the exposure distribution and the effect of source reduction in three main sources groups. In each of the annual concentration classes a quantified damage by pollution may be determined. This may be below certain exposure levels and the total damage may be determined by integrating the damage function over the exposure distribution. DT O = ANk Dk,O k ANk, the number of people in each concentration class k Dk :the specific damage function for the annual average concentration class k. The total damage function DT may be determined for different source reduction schemes. Additional exposure due to the activity pattern of the population. The exposure is first calculated for people staying at home. When people's activity pattern is better known additional exposure may be calculated accordingly. Commuters and drivers/policemen should be considered when the damage function is further developed. It is estimated that approximately 30% of the population in Jakarta make regular trips along roads every day and spend 1-2 hours close to roads with high traffic intensity every day. This means an addition of 15-30 pg/M3 to their home exposure. Drivers and street workers spend approximately 8 hours in traffic environments every day, i.e. the additional exposure amounts to (400 Alg TSP /rnCHOM E) 6 = 25-75 ig TSP / m Approximately 300,000 "road workers" are exposed to this annual average additional pollution stress. The low end of the range applies for the people living in the center and the high end applies for the people living in the suburbs. According to the statistical survey of Jakarta, 290,000 people work in industry -and some of them are exposed to an additional pollution load in their occupational environment. In some industrial environments the air will be more polluted than air close to the main roads. The number of people exposed to this additional stress is probably quite small. The exposure calculations are based upon annual average TSP-concentrations. To evaluate the PM1O exposure the fraction PM1O/TSP should be estimated for each source group, and the TSP- values transformed to PM1o values before the exposure calculations. This procedure was followed in the URBAIR Kathmandu study. In Jakarta, PM1o concentrations were assumed to be 55% of the TSP-concentrations. Table 1: Number of residents in Jakarta exposed to different levels of TSP-concentrations outside their homes Cs [Cl C2 ] N, > C2 AN P AP Traffic reduction Industry reduction Domestic reduction .tglm3 ig/m3 inh. % % 25% 50% 25% 50% 25% . 50% 80.0 90.0 6,458,608 0 100.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 90.0 100.0 6,454,574 4,034 99.938 0.062 0.225 0.792 0.062 0.314 0.062 0.062 100.0 110.0 6,400,467 54,107 99.100 0.838 1.458 3.741 0.987 1.257 0.838 0.838 110.0 120.0 6,272,124 128,343 97.113 1.987 3.794 11.120 2.494 3.398 2.190 2.439 120.0 130.0 6,024,203 247,921 93.274 3.839 7.485 19.039 4.437 5.806 3.976 4.065 130.0 140.0 5,668,254 355,949 87.763 5.511 11.207 19.477 6.873 8.571 5.170 5.357 140.0 150.0 5,106,759 561,495 79.069 8.694 13.964 30.877 9.416 9.281 8.973 9.366 150.0 160.0 4,454,121 632,638 68.964 10.105 13.167 10.570 11.598 9.683 10.190 11.491 160.0 170.0 3,835,884 618,237 59.392 9.572 13.172 1.774 7.440 9.383 10.115 8.430 ..........i .6.......... ................................................................................................................................................................................................................................................ 170.0 180.0 - 3,320,573 515,311 51.413 7.979 23.949 0.059 9.870 11.354 7.511 8.270 180.0 190.0 2,478,595 841,978 38.377 13.037 6.219 0.000 9.175 9.476 12.597 11.305 190.0 200.0 1,446,275 1,032,320 22.393 15.984 1.522 0.000 8.926 18.088 18.792 18.792 200.0 210.0 807,480 638,795 12.502 9.981 0.000 0.000 7.784 4.611 7.083 7.700 210.0 220.0 424,136 383,344 6.567 5.935 0.000 0.000 4.370 3.676 5.935 5.318 220.0 230.0 329,558 94,578 5.103 1.464 0.000 0.000 1.464 0.000 1.464 1.464 230. 240.0 329,558.0 .5.103 0.000 0.000 0.000.0.000.0.0000.0000.... 00 240.0 240.0 329,558 0 5.103 0.000 0.000 0.000 0.000 0.000 0.000 0.000 240.0 250.0 329558 0 5.103 0.000 0.000 0.000 0.000 O.000 0.000 0.000 250.0 260.0 329,557 1 5.103 0.000 0.000 0.009 0.000 0.O00 0.000 0.000 260.0 270.0 329,276 281 5.098 0.004 0.015 0.049 0.006 0.012 0.004 0.008 270.0 280.0 328,246 1,030 5.082 0.016 0.055 0.226 0.019 0.039 0.016 0.012 280.0 290.0 325,169 3,077 5.035 0.048 0.130 0.473 0.075 0.069 0.048 0.059 290.0 300.0 317,409 7,760 4.915 0.120 0.296 1.034 0.132 0.169 0.132 0.136 300.0 310.0 304,915 12,494 4.721 0.193 0.482 0.640 0.292 0.337 0.194 0.236 310.0 320.0 283,503 21,412 4.390 0.332 0.620 0.119 0.356 0.523 0.358 0.348 320.0 330.0 249,940 33,563 3.870 0.520 1.378 0.001 0.611 0.629 0.509 0.539 330.0 340.0 203,937 46,003 3.158 0.712 0.679 0.000 0.516 0,609 0.684 0.606 340.0 350.0 125,549 78,388 1.944 1.214 0.172 0.000 1.496 1.510 1.425 1.425 ..........i d................~ ...................................................................I.................................I.....................................................................................................I............ ......................... 350.0 360.0 73,132 52,417 1.132 0.812 0.000 0.000 0.664 0.573 0.600 0.670 360.0 370.0 14,852 58,280 0.230 0.902 0.000 0.000 0.707 0.633 0.902 0.832 370.0 380.0 0 14,852 0.000 0.230 0.000 0.000 0.230 0.000 0.230 0.230 380.0.... ......... 390.0 0 0, 0.000 0.000 0.00 , 0 .0.00 .00 .0.0 390.0 400.0 0 0 0.000 0.000 0.000 0.000 0.000 0,000 0.000 0.000 390.0 400.0 0 0 0.000 0.000 0.000 0.000 0.000 0.000 -0.000 0.000 Cs [C1, C2 j: concentration interval Nc > C: cumulative concentration dist. AN: number of people in each pollution P cumulative concentration distribution in percent of total population. A?: percentage of population in each concentration interval. Emission reduction: Percentage of population in each concentration interval after emission reduction. APPENDIX 7: SPREADSHEETS FOR CALCULATING EFFECTS OF CONTROL MEASURES ON EMISSIONS EMISSIONS SPREADSHEET The spreadsheet is shown in Figure 1 and Figure 2. (Examples: TSP and NOx emissions, DKI Jakarta, Base Case Scenario, 1990.) Figure 3 shows TSP emission contributions in absolute and relative terms. The purpose of the spreadsheet is to calculate modified emission contributions, due to control measures, such as new vehicle technology, improved emission characteristics, achieved by measures on existing technology, and reduced traffic activity/fuel consumption. The emissions are calculated separately for large point sources (with tall stacks) and for area sources and smaller distributed point sources. The reason is that air pollution concentrations and population exposures are calculated differently for these two types of source categories. The columns and rows of the worksheet are as follows: Columns (a) q Emission factor, g/km for vehicles, kg/m3 or kg/ton for fuel combustion and process emissions; - for vehicles, emission factors are given for "existing" and "new" technology. (b) F,T Amount of "activity;" - F (m3 or ton) for fuel consumption in industrial production. - T (vehicle km) for traffic activity. (c) qF,qT Base case emissions, tons, calculated as product of columns (a) and (b). (d) fq, fF, ff, f- Control measures. Relative reduction of emission factor (fq), amount (fF, fT) or other (f-) resulting from control measures. (e) qF fq fF f-: Modified emissions, due to control measures. (f) d(qF fq fF f-) Relative emission contributions from each source category such as vehicles, fuel combustion, and industrial processes. (g) d(qF fq fF f-) Relative emissions contributions, sum of all categories. Rows (a) Separate rows for each source type and category, "existing" and "new" technology. (b) "Background": Fictitious emissions, corresponding to extra-urban background concentration. (c) Modified emission(s): ratio between modified and base case emissions. 133 134 Appendix 8 Figure 1: URBAIR spreadsheet for emissions calculations TOTAL ANNUAL EMISSIONS, JAKARTA Particles, scenario: 1990 Emission Amount Base- Control measures Modified Relative Relative factor case emissions emissions emissions Emissions per category total LARGE POINT SOURCES q F qF fq fF f- qF fq fF f- d(qF fq fF f-) d(qF fq fF f.)tot (kg/mr3) (10E3.3) (loEG kg) (10E6 kg) (p-r,enq ¶ (p-rnt) Power plants 0,00 1,00 1,00 1,00 0,00 #0IVIOI 0,00 #DIV/01 0.00 #DIV/O! Sum large point sources 0,00 0,00 _#DIV1oI Modifled emissions/emissions, polnt sourc. #DIV/0! AREA SOURCES AND DISTRIBUTED POINT SOURCES Vehicles q T q T fiq fT f- qT fq fT t- d(qT fq fT I-) d(qT fq fT I-) (fgkmI) (10E6 k./y) (10E3 kg/yj (10E3 kg) (p.r-t) Gasoline Pass cars 0,20 5659 1132 1 1 1 1132 3,3 1,2 Pick-up Sc. 0,33 365 120 1 1 1 120 0,4 0,1 Truck medium 0,68 38 26 1 1 1 26 0,1 0,0 Bus 0,68 183 124 1 1 1 124 0,4 0,1 Bajaj 0,50 589 295 1 1 1 295 0,9 0,3 MC 0,50 4438 2219 1 1 1 2219 6,5 2,3 Sum gasoline 11272 3916 3916 11.4 4.0 Modified emlsslonslem Issioi , gasoline 1,00 Diesel Pass. cars 0,6 1415 849 1 1 1 849 2,5 0,9 Pick up etc. 0,9 365 329 1 1 1 329 1,0 0,3 Truck medium 2 154 308 1 1 1 308 0,9 0,3 Truck heavy 2 1 2 1 1 1 2 0,0 0,0 Bus, Coplet etc. 0,9 408 367 1 1 1 367 1,1 0,4 Bus regular 2 301 602 1 1 1 602 1,e 0,6 Sum diesel 2644 2457 2457 7,2 2,5 Modified emissionslemissions, diesel 1 Resuspension 1 2 13916 27832 1 1 1 27832 81,4 28.8 Modified emissions/emissions resuspension 1 Sum total vehicles I 34205 34205 100,0 35 Modified emisslonstemissions, total vehicles 1,00 Fuel comrnbustlon q F qF fq fF 1f qF fq fF I- d(qF tq fF t-)fuel duqF fq fF (-)tot (kg/l.3) (103E33) (10E3 kg) (10E3 kg) (percnu-) (p ....e Industrisalcom m ercIal I Distillate fuel 0,3 8 18,0 185.4 1,00 1,00 1,00 185,4 1,8 0,2 Coal 7,50 0,1 0,4 1,00 1,00 1,00 0,4 0,0 0.0 Coke 5,00 2,5 12,5 1,00 1,00 1,00 12,5 0.1 0.0 Gas 0,048 63.0 3,0 1,00 1,00 1,00 3,0 0.0 0,0 Domestictsmall Industry Fuel oil 1,40 1202,0 1682,8 1,00 1,00 1,00 1682,8 16,0 1,7 Distillate fuel 1,40 1155,0 1617.0 1,00 1,00 1,00 1617.0 15.3 1,7 Gas 0.048 163,0 7.8 1,00 1.00 1,00 7.8 0,1 0,0 Open burning 8,00 878,4 7027,0 1,00 1,00 1,00 7027,0 66,7 7,3 Sum fuel combustion 10535,9 10535,9 100.0 10,9 M odified em IssIons/em IssIons, fuel 1,00 Industrial processes q F qF fq IF f- qF fq IF f- d(qF fq fF f-)ind. d(qF fq fF f-)tot (10E3 k9gy) (n . *s) (p. n r) (parcenl) Food and textile 10.0 939 9390 1 1 1 9390 29,5 9,7 Wood and prod. 17,6 131 2306 1 1 1 2306 7.2 2.4 Paper and pr. 27,0 193 5211 1 1 1 5211 16,4 5,4 Chemicals 10,0 380 3800 1 1 1 3800 11.9 3,9 Non met, mineral prod 45.0 38 1710 1 1 1 1710 5,4 1,8 Iron and steel 25.0 378 9450 1 1 1 9450 29.7 9.8 Sum Industrial processes 31867 31867 100,0 32,9 M odified em lsslons/emissions, Ind proc. 1,00 Miscellaneous q M qM fq fM 1- qM fq fM i- d(qM fq fM f-)misc d(qM fq IM f-)tot (kg/LTD) (LTD) (p-rcn ) Ip.-nt) Airports 0.355 73411 26 1 1 1 26 0.1 0.0 Construction 20000 1 1 1 20000 99,4 20,7 Harbour 100 1 1 1 100 0,5 0,1 Sum miscellaneous 2012E 20126 100,0 20,8 Modified emissions/emisslons, misc, 1.00 "Background- | Unknown Sum total, excl. "Background" 96731 T| 96733 100 |Modified emissionslemissions, total | 1.00 URBAIR-Jakarta 135 Figure 2: Total annual emissions, DKI Jakarta. NO,N (1990) TOTAL ANNUAL EMISSIONS, JAKARTA NOx, scenario: 1990 Emission Amount Base- Control measures Modified Relative Relative factor case emlssions emissions emissions I_________ ____Emissions per category total LARGE POINT SOURCES q F qF fq fF f- qF Iq fF f- d(qF fq fF I-) d(qF fq IF f-)tot (kg/m3) (tOE3n3) f(IOE6 kg) __oe6 kg) (p.lu-nl) (p.ru.nt) Power plants 0,00 1,00 1.00 1,00 0,00 #DIV/01 0,00 #DIV/0O 0,0 #DIV/0I Sum large point sources 0,00 0,00 JDIVJOI Modified emissions/emissioni, point sourc. #DIVIOI AREA SOURCES AND DISTRIBUTED POINT SOURCES Vehicles q T qT fq fT f- qT fq fT f- d(qT fq fT f-) d(qT fq fT I-) (g1kn) (loEs k./y) (IOE3 kgIyeall (1OE3 kg) (p.r nt) (p.,o.nt Gasoline Pass. cars 2,70 5659 15279 1 1 1 15279 48,4 35,5 Pick-up etc. 2,70 365 986 1 1 1 986 3,1 2,3 Truck medium 8.00 38 304 1 1 1 304 1,0 0.7 Bus. Coplet etc. 8,00 183 1464 1 1 1 1464 4,6 3,4 Bajaj 0,07 589 41 1 1 1 41 0,1 0,1 MC 0,07 4438 311 1 1 1 311 1.0 0,7 Sum gasoline 11272 18385 18385 58,3 42,7 Modified emissions/emissions, gasoline 1,00 Diesel Pass. cars 1 1415 1415 1 1 1 1415 4,5 3,3 Pick up etc. 1,4 365 511 1 1 1 511 1,6 1.2 Truck medium 13 154 2002 1 1 1 2002 6.3 4,7 Truck heavy 13 1 13 1 1 1 13 0,0 0,0 Bus, Coplet etc. 13 408 5304 1 1 1 5304 16,8 12,3 Bus regular 13 301 3913 1 1 1 3913 12,4 9,1 Sum diesel I 2644 13158 13158 41,7 30,6 Modified emissions/emissions, diesel 1 Sum total vehicles | 31543 31543 100,0 73 Modified em lsions/emissions, total vehicles 1,00 Fuel combustion q F qF fq IF If qF fq fF t- d(qF fq fF f-)fuel d(qF fq fF f-)tot Iks/n,3) (1OE3.3) (O E3 kgly) (1OE3 kg) (p-.o.nt) (perontI) Industrial/commercial Distillate fuel 2 618 1483 1,00 1.00 1,00 1483 15,1 3,4 Coal 11 0 1 1,00 1,00 1,00 1 0,0 0,0 Coke 10 3 26 1,00 1,00 1,00 26 0,3 0,1 Gas 2,24 63 141 1,00 1.00 1,00 141 1,4 0,3 Domestic/small industry Fuel oil 2 1202 2404 1,00 1,00 1,00 2404 24,5 5,6 Distillate fuel 2 1155 2772 1,00 1,00 1,00 2772 28,2 6,4 Gas 2,24 163 365 1,00 1,00 1,00 365 3,7 0,8 Open burning 3 878 2635 1,00 1,00 1,00 2635 26,8 6,1 Sum fuel combustion 9827 9827 100,0 22,8 Modified emisslonsJemissions, fuel 1 00 Industrial processes q F qF fq IF f- qF fq IF 1- d(qF fq fF f-)ind. d(qF tq fF f-)tot (IOE3 kg/y) (n.01 W.t.) lp.r-nt) (p.r-ent) 0 1 1 1 0 #DIV/0 0,0 0 1 1 1 0 #DIV/0o 0,0 0 1 1 1 0 #DIV/0I 0,0 0 1 1 1 0 #DIV/01 0,0 0 1 1 1 0 #DIV/0I 0,0 0 1 1 1 0 #DIV/0I 0,0 Sum industrial processes 0 a #DIV/OI 0,0 Modified emissions/emissions, ind. proc. #DIV/01 Miscellaneous q M qM fq IM f- qM fq fM I- d(qM fq fM f-)misc d(qM Iq fM f-)tot (kg9LTD) (LTD) (pa-cpnt) (p.,o-nt) Airports 9 73411 661 1 1 1 661 39,8 1.5 Harbour I 1000 1 1 1 1000 60,2 2,3 Sum miscellaneous 1661 1661 100,0 3,9 Uoditied emissions/emissions, misc. 100 'Background' Unknown Sum total, excl. 'Background" 430301 43030 100 Modified emissionslemissions, total .. 1,00_ 136 Appendix 8 Figure 3: Emissions contributions from various source categories Present 35000-- .~30000- 25000- I: Large point Gasoline Diese1 Resusp. Fuel Ind. proc. Misc. sources conbusfion APPENDIX 8: METEOROLOGY AND DISPERSION CONDITIONS IN JAKARTA GENERAL DESCRIPTION OF DISPERSION AND EFFECTS OF TOPOGRAPHY/CLIMATE IN THE JAKARTA REGION In general, the atmospheric circulation over Indonesia is affected by the meridional circulation termed Hadley circulation or trade wind. When the sun moves toward the southern hemisphere, the north east trade wind is attracted to the south, crossing the equator and becomes west or northwest monsoon in the rainy season (January-June). On the contrary, when the sun moves toward the northern hemisphere the east or southeast monsoon is created (the dry season, July- December). Normally, Indonesia experiences relatively low wind speeds. In the coastal regions of Indonesia local land or sea breeze may cause stagnation in the air when it is directed against the monsoon. Seasonal variations may occur with stagnation in the mornings during the rainy season and in the evenings during the dry season. The dispersion of pollutants may therefore vary with season and time of day. The topography of Indonesia is dominated by the volcanic belt which runs from the western tip of Sumatra to the eastern Irian Jaya and from the northern tip of Sulawesi to the southern part. In the western and central parts of Java the topography has an important effect on the dispersion conditions. The climate of Indonesia belongs to the tropical maritime continent type and is described as one of the most humid regions of the world. The humidity varies between 70-90%. GEOGRAPHY, TOPOGRAPHY AND CLIMATE IN JAKARTA Jakarta is the biggest city in Indonesia, and is located on the mouth of the Ciliwung river. The city is located 6°12'S and 106°48'E. The area is very smooth with no local topography that can affect the dispersion conditions (average height 7 m a.s.l.). The climate is very hot and humid. Because Jakarta lies so close to the equator, the solar heating during the day and the earth cooling during the night may produce local land-sea breeze. When the land-sea breeze is working against the monsoon, it causes a stagnation of the airmasses, allowing pollutant concentrations to build up significantly. 137 138 Appendix 8 Figure 1: Seasonal variation of the frequency of wind direction and wind speedfor the BMG weather station in the DKI Jakarta area . - - 30 --' 20 - 20 '10 ~ ~ ~ - =10 January April - 30 l- -20 =20 _-_ ~10 July October - 30 _-= 20 10 :I - 3 knet :4 - 6 knet Annual : >7 knet URBAIR-Jakarta 139 The Agency of Meteorology and Geophysics (BMG) is running six weather stations spread in the DKI Jakarta and BOTABEK area. The measurements consist of: * air temperature, * air humidity, * wind speed, * wind direction, . cloudiness, * barometric pressure, * rainfall, * rainy days. The mixing height is derived from upper air measurement by means of the rawindsonde. The upper air data are obtained from the Soekarno Hatta International Airport. Two-way frequency distribution of wind speed and direction is derived for the six weather stations in the DKI Jakarta area. The wind is categorized into 8 directions and 4 classes of speed (0; 1-3 knots; 4-6 knots; and 7 knots and more. Atmospheric stability is derived from upper air measurement by means of the tethered radiosonde. The atmospheric stability is classified according to Pasquill's classification. The applicability of different methods of classification in Jakarta should be investigated. Neutral conditions were used for the calculations of yearly average concentrations. Wind speed and direction. The wind roses from the six stations in DKI Jakarta, Figure 2 and 3 show similar patterns. The distance between the adjacent existing weather stations is not significant. The weather station that is located at the BMG office is used as a representative station. The DKI Jakarta area is situated in the coastal region, consequently it is affected by the local winds, especially sea and land breeze. Although the local winds often affect the wind pattern, the prevailing wind in the DKI Jakarta is still governed by the monsoon. These two winds reinforce each other when they blow in the same direction and weaken each other when they blow in the opposite direction. The sea breeze occurs at the coastline on sunny days, due to the warming of the land and a temperature gradient from sea to land is developing. The sea breeze may penetrate several kilome- tres into the inland (more than 40 km) when the temperature difference between sea and land is sufficiently large. In general the sea breeze starts to blow around 10 o' clock in the morning and it reaches its maximum when the inland air temperature is at its maximum. The local sea breeze comes from the north east direction. In the rainy season the sea breeze is weaker than in the dry season due to the effect of clouds on the solar warming. The annual isotachs (iso-curves for wind speed) of the region, shown in Figure 4, show that the wind speed is weakest at Ciledug. The weather station in Ciledug is affected by local forcing. This may be due to a channel effect through the street canyons. The dominant wind direction in Jakarta during the southern summer is from west to north. When the prevailing winds come from the northwest, the dominant wind direction at Ciledug is from the north. In July during the southern winter, the prevailing winds in Jakarta come from northeast to east. The station in Ciledug is affected by local forcing with dominant wind direction east west. The location of the Ciledug weather station should be evaluated with respect to local effects. 140 Appendix 8 Figure 2: Map over the DKI Jakarta area with windroses from the six weather stations in CENGKARENG JANUAry 1989.86 G 130 l te \ TJANUARYN1989.86P CILEOU6G MAUMPK JANUARY 1989.86 G *JANUARY 1989,86 G ALANG SANWAYA JANUARY 1989,86G URBAIR-Jakarta 141 Figure 3: Map over the DKI Jakarta area with windrosesfrom the six weather stations in July (0600 GMT, 1300 local time) tT7AUNG PRIUK e. I 1. GMT CENGKARENG JUU 1989.86 GMT BMG X s JUU 1989.86 MT _, ''\\ ''~~~~~~~. X CLEDUG " JUU 1989.86GMT GJU MAUM PK 4UUW89.MGN 189.f GM ALANG SANJAYA -~~~~~U 1998 G W1w g6 142 Appendix 8 The winds are generally from calm to Figure 4: Average annual isotachs in the DKI Jakarta area weak in the morning while in the afternoon the winds are from weak to strong. This is due to the land-sea breeze. The local winds modify the / monsoon winds. The wind speed JAKARATA (SMO) pattern varies through _ Jakarta. To the 3 northwest there are sharp gradients of the PL wind speed from Cengkareng to Ciledug that lies in an area with calm winds (annual average about 2 knots). The main station Jakarta BMG lies in the strong gradient field between the calm area in Ciledug and the harbor area that is strongly affected by the sea breeze during the day. The annual average wind speed for Jakarta BMG is about 4-5 knots. In the 4 southern part of A a Jakarta, at Atang BOGOR Sanjaya, the wind speed is about the same as at BMG, and stronger than at Ciledug. The mixing height. The mixing height is a parameter that describes the level where an air parcel, after being heated, will continue to rise until its temperature equals the surrounding air tempera- ture. The airmass under the mixing height is well mixed and therefore often referred '- as the mixing layer. The mixing heights for the DKI Jakarta region are given in Table 1. URBAIR-Jakars 143 The mixing height depends on Table 1: Mean mixing height (m) in the DKI Jakarta the maximum air Area temperature and the Months Jakarta Jakarta Jakarta Jakarta Jakarta Average mixing height in weather conditions. Pusat Selatan Timur Utara Barat DKI Jakarta The monthly average January' 565 495 495 596 481 526.4 mixig high inthe February 496 429 452 582 388 469.4 mixing height in the March 952 712 840 1,033 840 891.4 DKI Jakarta varies April 820 714 741 965 661 780.2 from 469 m to 1,174 May 1,007 961 944 1,159 927 999.6 m and the annual June 1,020 958 925 1,134 886 984.6 average mixing July 1,149 1,074 1,053 1,226 995 1,099.4 height is 902 m. August 1,213 1,199 1,155 1,252 1,049 1,173.6 October 1,091 1,058 1,059 1,178 1,091 1,095.4 November 848 815 872 927 794 851.2 Atmospheric December 814 738 738 857 738 777.2 stability. The Source: BMG Jakarta (1989). atmospheric stability plays an important role in the dispersion of pollutants. The atmospheric stability is determined by vertical temperature profiles. The vertical lapse rate is classified according to Pasquill as follows: A: Extremely unstable conditions. B: Moderately unstable conditions. C: Slightly unstable conditions. D: Neutral conditions. E: Slightly stable conditions. F: Moderately stable conditions. In the east of Jakarta (Pulo Gadung and Halim Perdana Kusumah) the frequency distribution of the atmospheric stability was in May 1990 33% extrernely unstable, 43% neutral and 14% slightly stable. The daily variation of the atmospheric stability in East Jakarta is given in Table 2. The table shows that the stable conditions occur during the morning and evening and the unstable conditions are at a maximum in the middle of the day. Table 2: The diurnal variation of The frequency of neutral conditions varies only stability in the eastern part of the DKI slightly as function of time of day. Jakarta area Stability Temperature. The average annual temperature in Time Extremely Neutral Slightly stable Jakarta is about 27°C. The temperature in Jakarta has unstable conditions conditions only got a slight annual variation, about 1-1.5°C conditions variation. This is caused by the tropical monsoon near 1000 18 23 28 the equator. 1300 45 16 - 1600 18 23 44 Rainfall. The annual rainfall is approximately 2000 Source: BMG Jakarta (1990). mm. The amount of rainfall varies significantly within the DKI Jakarta region. The annual range of rainfall variation in Central Jakarta is 362 mm, in South Jakarta 313 mm, in East Jakarta 336 mm, in North Jakarta 478 mm, and in West Jakarta 396 mm. 144 Appendix 8 There are four seasons in Jakarta: the rainy season, the first transition season, the dry season and the second transition season. The rainy season is characterized by west or northwest monsoon and the dry season by east or southeast monsoon. For both west and east monsoons the amount of rainfall and number of rainy days increase toward the south region (Bogor). The orographic effect and the local sea and valley breeze contribute to the cloud and rain formation on the windward side. The rain in DKI Jakarta is dominated by the west monsoon. The amount of rainfall and the number of rainy days is much greater in December-Fibruary than in June-August. ADVERSE METEOROLOGICAL SITUATIONS IN JAKARTA Studies in the Jakarta area indicate weak and short-lived inversions. The inversions break up as soon as the sun rises. One meteorological situation that can lead to high ground level concentrations will be when the local land-sea breeze blows against the monsoon, and the local wind is faster than the monsoon. This could happen during the early mornings when the sky is clear, when the airmass in the inland is cooled from below by ground infrared radiation. The airmass will tend to follow the topography towards the coast. In the Jakarta area the wind will probably follow the river valleys from south to north. When the northwest monsoon is blowing, the local wind and the monsoon can lead to stagnation of the airmasses, leading to pollutant build-up. The combination of the weak wind speed and unstable atmospheric conditions in the daytime can lead to high ground level concentrations near point sources (stack emissions) due to the vertical turbulent motions. The plume may not be much diluted before the downdrafts move the plume towards the ground. APPENDIX 9: PROJECT DESCRIPTION, LOCAL CONSULTANTS PROJECT DESCRIPTION REGARDING AIR QUALITY ASSESSMENT Information should be collected regarding the items described below. The information to be collected shall go beyond the information contained in the material referenced in the Draft Report from NILU and Institute of Environmental Studies (IES) of the Free University of Amsterdam prepared for the Workshop, and summarized in that report. Available information shall be collected regarding the following items, and other items of interest for Air Quality Management System Development in DKI Jakarta: D Meteorological measurements in and near the city. * Activities/population data for DKI Jakarta: - Fuel Consumption data: Total fuel consumption (1) per type (high/low sulfur oil, coal, gas, firewood and other biomass fuels, other) and (2) per sector (industry, commercial, domestic) - Industrial plants: Location (on map), type/process, emissions, stack data (height, diameter, effluent velocity and temperature) - Vehicle statistics: 1. number of vehicles in each class (passenger cars, small/medium/large trucks, buses, motorcycles (2- and 3-wheels, 2- and 4-stroke); 2. Age distribution; 3. Average annual driving distance per vehicle class. - Traffic data: Definition of the main road network marked on map. Traffic data for the main roads: 1. annual average daily traffic (vehicles/day) 2. traffic speed (average, and during rush hours) 3. vehicle composition (passenger cars, motorcycles, trucks/buses). - Population data: Per city district (as small districts as possible) 1. total population; 2. age distribution. 145 146 Appendix 9 * Air pollution emissions - Emission inventory data (annual emissions) 1. per compound (SO2, NOx, particles in size fractions: <2 ,ug, 2-10 jig, >10 jIg, VOC, lead) 2. emissions per sector (industry, transport, domestic, etc.) * Air pollution data: - concentration statistics per monitoring station: 1. annual average, 98 percentile, maximum concentrations (24-hour, 1 hour) 2. trend information; 3. methods description, and quality control information on methods. * Dispersion modeling: Reports describing studies and results. * Air pollution laws and regulations: Summary of existing laws and regulations. * Institutions: - Description of existing institutions working in and with responsibilities within the air pollution sector, regarding: 1. monitoring; 2. emission inventories 3. law making; 4. enforcement. - The information shall include: 1. responsibilities and tasks of the institution; 2. authority; 3. manpower; 4. expertise; 5. equipment (monitoring, analysis, data, hard/software) 6. funds. It is important that the gathering of information is as complete as possible regarding each of the items, so that we have a basis of data which is as updated and complete as possible. Remember that this updated completed information database is to form the basis for an action plan regarding Air Quality Management in DKI Jakarta. Such an action plan will also include the need to collect more data. In that respect, it is very important that the gathering of existing data is complete. URBAIR-Jakarta 147 PROJECT DESCRIPTION REGARDING DAMAGE ASSESSMENT AND ECONOMIC VALUATION URBAIR: TOPICS FOR RESEARCH Physical Impacts 1. Describe available studies on relations between air pollution and health. 2. Decide on the acceptability of dose-effect relationships from the United States. a) Mortality: 10 ,g/m3 TSP leads to 0.682 (range: 0.48-0.89) percentage change in mortality. b) Work loss days (WLD): 1 pg/m3 TSP leads to 0.00145 percentage change in WLD. c) Restricted activity days (RAD): 1 pg/M3 TSP leads to 0.0028 percentage change in RAD per year. d) Respiratory hospital diseases (RHD): 1 pg/m3 TSP leads to 5.59 (range: 3.44-7.71) cases of RHD per 100,000 persons per year. e) Emergency room visits (ERV): 1 pg/m3 TSP leads to 12.95 (range: 7.1-18.8) cases of ERV per 100,000 persons per year. f) Bronchitis (children): 1 pg/rM3 TSP leads to 0.00086 (range: 0.00043-0.00129) change in bronchitis. g) Asthma attacks: 1 Pg/m3 TSP leads to 0.0053 (range: 0.0027-0.0079) change in daily asthma attacks per asthmatic persons. h) Respiratory symptoms days (RSD): 1 pg/M3 TSP leads to 1.13 (range:0.90-1.41) RSD per person per year. i) Diastolic blood pressure (DBP): change in DBP = 2.74 ([Pb in blood]1Id-[Pb in blood]new) with [Pb in blood] is blood lead level (pg/dl). j) Coronary heart disease (CHD): change in probability of a CHD event in the following ten years is: [1 + exp - (-4.996 + O.030365(DBP)Jj' - 1[ + exp - (-4.996 + 0.030365(DBP2)J-' i) Decrement IQ points: IQ decrement = 0.975 x change in air lead (pg/m3) Calculation example: * Let population be 10 million people. * Let threshold value of TSP be 75 pg/m3 (the WHO guideline). * Let the concentration TSP be 317 pg/M3. X Concentration-threshold = 317 - 75 = 242 = 24.2 (10 [tg/M3). = Change in mortality = 24.2 x 0.682 = 16.5%. * Let crude mortality be 1% per year. =X Crude mortality = 100,000 people per year. =X Change in mortality due to TSP = 16.5% of 100,000 people = 16,500 people per year. 3. For those dose-effect relationships that are acceptable, base value must be gathered, e.g.: a) crude mortality b) present work days lost c) etc. 148 Appendix 9 Valuation 1. Mortality. a) Willingness to Pay. In the United States research has been carried out on the relation between risks of jobs and wages. It appeared that 1 promille of change in risk of mortality leads to a wage difference of ca. US$ 1,000. If this figure is applicable to all persons of a large population (10 million), the whole population values I promille change in risk of mortality at US$1,000 x 10 x 106 = US$10 billion. An increase in risk of I promille will lead to ca. 10,000 death cases, so per death case the valuation is US$1 million. It should be decided if in other countries, c.q. cities, this valuation should be corrected for wage differences (e.g. if the average wage is 40 times lower than in the United States, the valuation of I death case is US$25,000). If this approach is acceptable, the only information needed is average wage. b) Production loss. If the approach of willingness to pay is not acceptable, the alternative is valuing human life through production loss, i.e. foregone income of the deceased. Again. the information needed is average wage. Moreover, information is needed on the average number of years that people have a job. However, those without a job should also be assigned a value. An estimate of the income from informal activities can be an indication. Otherwise a value derived from the wages (e.g. half the average wage) can be a (somewhat arbitrary) estimation. 2. Morbidity. Estimates are needed for all cases of morbidity of the duration of the illness, so as to derive an estimation of foregone production due to illness. Just as in the case of mortality (B. 1.b) wages can be used for valuation of a lost working day. Moreover, the hospital costs and other medical costs are to be estimated. These costs still do not yet include the subjective costs of illness, which can be estimated using the willingness-to-pay approach to pay to prevent a day of illness. 3. Willingness to Pay to prevent a day of illness. Valuation in the United States, based on surveys among respondents, indicate that the willingness to pay to prevent a day of illness is approximately US$15. This amount could, just like the amount of willingness to pay for risk to human health, be corrected for wage differences. The acceptability of such a procedure is, perhaps, somewhat lower. 4. IQ Points. Loss of IQ of children may lead to a lower earning capacity. A U.S. estimate is approximately US$4,600 per child, per IQ point, summed over the child's lifetime. If this is acceptable, the figure could be corrected for wage differences between the United States and the city. Other Impacts. 1. Buildings. An estimate by Jackson et al is that prevented cleaning costs per household per year are US$42 for a reduction in TSP concentration, from 235 ,ug/m3 to 115 jig/m3. This would imply a benefit of US$0.35 per household per pg/m3 reduction. This figure could be corrected for wage differences between the United States and the city. If that is acceptable, the information needed is the number of households in the city. 2. Monuments. It is difficult to say which value is attached to monuments, as they are often unique and their value is of a subjective character. Nevertheless, the restoration and cleaning costs of monuments could be an indication of the order of magnitude of damage to monuments. Revenue of tourism might also give a certain indication of valuation of future damage to monuments. URBAIR-Jakarta 149 Remark * In most cases, the valuation of damage is not very precise, and certainly not more than an indication of the order of magnitude. Technological Reduction Options. To give a reliable estimate of the costs of technological reduction options, one needs a reliable emission inventory in which is included the currently used technologies and the age and replacement period of the installed equipment. In the absence of this, the study by the city team might wish to concentrate on a case study (e.g. traffic, fertilizer industry, large combustion sources.) * The first step is to identify options. Cooperation with IES is possible, once a case study is identified. * The second step is to estimate the costs, i.e. investment costs and O&M (operation and maintenance) costs. Based on the economic lifetime of the invested equipment; the investment costs can be transformed to annual costs, using writing-of procedures. Costs will often depend to a large extent on local conditions. * The third step is to estimate the emission reductions of the various reduction options. * The fourth step is to rank the options according to cost-effectiveness. For this purpose the various types of pollution have to be brought under a common denominator. A suggestion could be to calculate a weighed sum of the pollutants, using as weights the amount by which ambient standards are exceeded on average. The calculation of the cost-effectiveness consists then of the calculation of the ratio of reduction over annual cost (R/C). The options with the highest ration R/C are the most cost- effective ones. Distributors of COLOMBIA GERMANY ISRAEL. NEPAL POTUGA SWEDEN DInoenlace Ltda. UNO-VERag Yozmot Lilerature Ud. Everest Media Iroemuational Services (P.) Ud. 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(358 0) 121-4435 Tehran URx: ht60 3) 755-4424 URL: ClI//xa Tel:co.34oopip88e3p9e RECENT WORLD BANK TECHNICAL PAPERS (continued) No. 351 Psacharopoulos, Morley, Fiszbein, Lee, and Wood, Poverty and Income Distribution in Latin America: The Story of the 1980s No. 352 Allison and Ringold, Labor Markets in Transition in Central and Eastern Europe, 1989-1995 No. 353 Ingco, Mitchell, and McCalla, Global Food Supply Prospects, A Background Paper Prepared for the World Food Summit, Rome, November 1996 No. 354 Subramanian, Jagannathan, and Meinzen-Dick, User Organizationsfor Sustainable Water Services No. 355 Lambert, Srivastava, and Vietmeyer, Medicinal Plants: Rescuing a Global Heritage No. 356 Aryeetey, Hettige, Nissanke, and Steel, Financial Market Fragmentation and Reforms in Sub-Saharan Africa No. 357 Adamolekun, de Lusignan, and Atomate, editors, Civil Service Reform in Francophone Africa: Proceedings of a Workshop Abidjan, January 23-2 6, 1996 No. 358 Ayres, Busia, Dinar, Hirji, Lintner, McCalla, and Robelus, Integrated Lake and Reservoir Management: World Bank Approach and Experience No. 360 Salman, The Legal Frameworkfor Water Users' Associations: A Comparative Study No. 361 Laporte and Ringold. Trends in Education Access and Financing during the Transition in Central and Eastern Europe. No. 362 Foley, Floor, Madon, Lawali, Montagne, and Tounao, The Niger Household Energy Project: Promoting Rural Fuelwood Markets and Village Management of Natural Woodlands No. 364 Josling, Agricultural Trade Policies in the Andean Group: Issues and Options No. 365 Pratt, Le Gall, and de Haan, Investing in Pastoralism: Sustainable Natural Resource Use in Arid Africa and the Middle East No. 366 Carvalho and White, Combining the Quantitative and Qualitative Approaches to Poverty Measurement and Analysis: The Practice and the Potential No. 367 Colletta and Reinhold, Review of Early Childhood Policy and Programs in Sub-Saharan Africa No. 368 Pohl, Anderson, Claessens, and Djankov, Privatization and Restructuring in Central and Eastern Europe: Evidence and Policy Options No. 369 Costa-Pierce, From Farmers to Fishers: Developing Reservoir Aquaculture for People Displaced by Dams No. 370 Dejene, Shishira, Yanda, and Johnsen, Land Degradation in Tanzania: Perceptionfrom the Village No. 371 Essama-Nssah, Analyse d'une repartition du niveau de vie No. 373 Onursal and Gautam, Vehicular Air Pollution: Experiencesfrom Seven Latin American Urban Centers No. 374 Jones, Sector Investment Programs in Africa: Issues and Experiences No. 375 Francis, Milimo, Njobvo, and Tembo, Listening to Farmers: Participatory Assessment of Policy Reform in Zambia's Agriculture Sector No. 376 Tsunokawa and Hoban, Roads and the Environment: A Handbook No. 377 Walsh and Shah, Clean Fuelsfor Asia: Technical Options for Moving toward Unleaded Gasoline and Low-Sulfur Diesel No. 378 Shah and Nagpal, eds., Urban Air Quality Management Strategy in Asia: Kathmandu Valley Report No. 380 Shah and Nagpal, eds., Urban Air Quality Management Strategy in Asia: Metro Manila Report No. 381 Shah and Nagpal, eds., Urban Air Quality Management Strategy in Asia: Greater Mumbai Report No. 382 Barker, Tenenbaum, and Woolf, Governance and Regulation of Power Pools and System Operators: An International Comparison No. 383 Goldman, Ergas, Ralph, and Felker, Technology Institutions and Policies: Their Role in Developing Technological Capability in Industry No. 384 Kojima and Okada, Catching Up to Leadership: The Role of Technology Support Institutions in Japan's Casting Sector No. 385 Rowat, Lubrano, and Porrata, Competition Policy and MERCOS UR No. 386 Dinar and Subramanian, Water Pricing Experiences: An International Perspective No. 387 Oskarsson, Berglund, Seling, Snellman, Stenback, and Fritz, A Planner's Guidefor Selecting Clean-Coal Technologiesfor Power Plants No. 388 Sanjayan, Shen, and Jansen, Experiences with Integrated-Conservation Development Projects in Asia No. 389 International Commission on Irrigation and Drainage (ICID), Planning the Management, Operation, and Maintenance of Irrigation and Drainage Systems: A Guidefor the Preparation of Strategies and Manuals No. 392 Felker, Chaudhuri, Gyorgy, and Goldman, The Pharmaceutical Industry in India and Hungary: Policies, Insititutions, and Technological Development No. 395 Saleth and Dinar, Satisfying Urban Thirst: Water Supply Augmentation and Pricing Policy in Hyderabad City, India THE WORLD BANK 1818 1i Strcct, NA .. W.ashin,(ton. D.C. 20433 USA tlcephlolnc: 202-477-1234 Facsimilc: 202-477-6391 TIcicx: .1Cl 64145 NVORIA)IANK 1:(CI 248423 VORI)AA.\NK \Xorld W\idc Nch: http://N% ww.NN orldhank.org/ F-mail: hooks(a NNorldhank.org METROPOLITAN ENVIRONMENTAL IMPROVEMENT PROGRAM lnvironnLcnt and Natural ResouLl CS l)ivision A\sia l'cchnical D)epartnicntIl1c Thoerld lHanik 1818 11 Strcet. N.AN. W ashington, 1).(. 20433 L 'SA Iclcplionc: 202-458-1598 Facsimilc: 202-522-1664 ISBN 0-8213-4035-2