WPS5686 Policy Research Working Paper 5686 Nigeria’s Infrastructure A Continental Perspective Vivien Foster Nataliya Pushak The World Bank Africa Region Sustainable Development Department June 2011 Policy Research Working Paper 5686 Abstract Infrastructure made a net contribution of around one GDP. The water and sanitation sector has inefficient percentage point to Nigeria’s improved per capita growth operations, with low and declining levels of piped water performance in recent years, in spite of the fact that coverage. Irrigation development is also low relative to unreliable power supplies held growth back. Raising the the country’s substantial potential. In the transport sector, country’s infrastructure endowment to that of the region’s Nigeria’s road networks are in poor condition from lack middle-income countries could boost annual growth by of maintenance, and the country has a poor record on air around 4 percentage points. transport safety. Among its African peers, Nigeria has relatively Addressing Nigeria’s infrastructure challenges will advanced power, road, rail, and ICT networks that cover require sustained expenditure of almost $14.2 billion the national territory quite extensively. Extensive reforms per year over the next decade, or about 12 percent of are ongoing in the power, ports, ICT, and domestic air GDP. Nigeria already spends about $5.9 billion. It is transport sectors. well placed to raise the funds needed for infrastructure, But challenges persist. The power sector’s operational given the strength of the national economy, abundant oil efficiency and cost recovery has been among the worst revenues, and efforts at electricity cost recovery and other in Africa, supplying about half of what is required, improvements to operations and management. with subsequent social costs of about 3.7 percent of This paper is a product of the Sustainable Development Department, Africa Region. It is part of a larger effort by the World Bank to provide open access to its research and make a contribution to development policy discussions around the world. Policy Research Working Papers are also posted on the Web at http://econ.worldbank.org. The author may be contacted at vfoster@worldbank.org. The Policy Research Working Paper Series disseminates the findings of work in progress to encourage the exchange of ideas about development issues. An objective of the series is to get the findings out quickly, even if the presentations are less than fully polished. The papers carry the names of the authors and should be cited accordingly. The findings, interpretations, and conclusions expressed in this paper are entirely those of the authors. They do not necessarily represent the views of the International Bank for Reconstruction and Development/World Bank and its affiliated organizations, or those of the Executive Directors of the World Bank or the governments they represent. Produced by the Research Support Team Nigeria’s Infrastructure: A Continental Perspective Vivien Foster and Nataliya Pushak Acknowledgments This paper draws upon a wide range of contributions from sector specialists from the Africa Infrastructure Country Diagnostic Team; notably, Dick Bullock on railways, Mike Mundy on ports, Heinrich Bofinger on air transport, Rupa Ranganathan on power, Carolina Dominguez on water and sanitation, Michael Minges and Rebecca Meyer on information and communication technologies, Alberto Nogales on roads, Nataliya Pushak on public expenditure, and Alvaro Federico Barra on spatial analysis. The paper is based on data collected by local consultants and benefited greatly from feedback provided by colleagues in the relevant World Bank country teams; notably, Onno Ruhl (Country Director), Shobha Shetty (Sector Leader), Mavis Ampah (ICT), Francois Onimus (irrigation), Prasad Tallapragada and Waqar Haider (power), Pierre Pozzo di Borgo (railways), Binyam Reja and Justin Runji (roads), Hassan Kida and Andrew Makokha (water). Contents Synopsis 1 A continental perspective 2 Why infrastructure matters 3 The state of Nigeria’s infrastructure 4 Roads 12 Rail 14 Ports 15 Air transport 18 Water supply and sanitation 20 Power 26 Water resources 30 Information and communications technologies 33 Financing Nigeria’s infrastructure 36 How much more can be done within the existing resource envelope? 41 Annual funding gap 43 What else can be done? 44 References and bibliography 46 General 46 Growth 46 Financing 46 Information and communications technologies 47 Irrigation 47 Power 48 Transport 48 Water supply and sanitation 49 iii Synopsis Infrastructure has made a net contribution of around 1 percentage point to Nigeria’s improved per capita growth performance in recent years, in spite of the fact that unreliable power supply held growth back. Raising the country’s infrastructure endowment to that of the region’s middle-income countries could boost annual growth by around 4 percentage points. Nigeria has made important strides toward improving much of its infrastructure. Compared to many African peers, Nigeria has relatively advanced power, road, rail, and information and communications technology (ICT) networks that cover extensive areas of the nation’s territory. In recent years, Nigeria has conducted several important infrastructure sector reforms. The ports sector has been converted to a landlord model, and terminal concessions now attract private investment on a scale unprecedented for Africa. The power sector is undergoing a restructuring, paving the way for performance improvements; the sector is finally on a path toward raising tariffs to recover a larger share of costs. Bold liberalization measures in the ICT sector have resulted in widespread, low-cost mobile services, Africa’s most vibrant fixed-line sector, and major private investments in the development of a national fiber-optic backbone. A burgeoning domestic air transport sector has emerged, with strong private carriers that have rapidly attained regional significance. But worrisome challenges persist in a number of areas, and loom the largest in the power sector. Inoperative generation capacity and lack of investment mean that the country has been able to meet only about half of its power demand. This, in turn, has resulted in an extremely unreliable supply; social costs can be conservatively estimated at 3.7 percent of gross domestic product (GDP). Meanwhile, the sector is hemorrhaging resources: historically, power users have been charged a fraction of the true cost of production, and the utility’s operational efficiency is among the worst in Africa. On a promising note, recent tariff and institutional reforms in the power sector have helped to significantly reduce hidden costs, saving about $1.3 billion (or 1.8 percent of GDP) per year. Notwithstanding this important gain, however, the hidden costs of Nigeria’s power sector remain the highest in West Africa. Less visible, but also disturbing, is the water and sanitation sector’s lack of development, compared to other services. Piped water coverage is only a fraction of the nation’s electrification rate, and access has been declining steeply in recent years, even as the practice of open defecation continues to rise. Moreover, water utilities appear no more efficient than the power utility. Irrigation development also remains low relative to the country’s substantial potential. Last but not least, Nigeria’s road networks are in relatively poor condition, testifying that assets are not being adequately maintained. The country’s poor air transport safety record is reason for further concern. Addressing Nigeria’s infrastructure challenges will require sustained expenditure of almost $14.2 billion per year over the next decade, or about 12 percent of GDP. (As a point of comparison, China spent about 15 percent of GDP on just infrastructure investment in the mid-2000s.) About $10.5 billion is needed for federal infrastructure alone, most of it for capital spending and power. Nigeria already spends $5.9 billion per year on federal infrastructure, equivalent to about 5 percent of GDP. Existing spending patterns are heavily skewed toward investment, with little provision for NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE operations and maintenance. (Information on the infrastructure spending of subnational governments was not available, and so could not be assessed.) A further $2.5 billion a year is being lost at the federal level due to inefficiencies of various kinds, most of them associated with the power sector. The underpricing of electricity is by far the single-largest source of inefficiency, even though cost-recovery tariffs would be affordable for the majority of the population. Low capital budget execution is also an issue across the infrastructure sector. When spending needs are set against current spending—and potential efficiency gains—an annual funding gap of $3.6 billion per year, or around 3 percent of GDP, is revealed. With its abundant oil revenues, Nigeria is relatively well placed to raise additional public finance for infrastructure. Given the size of the economy, more could also be done to leverage domestic capital markets, and there is scope to build on the comparative success of public-private partnerships. Nigeria has also attracted much interest from financiers outside the Organisation for Economic Co-operation and Development (non-OECD), notably China. In sum, Nigeria’s infrastructure challenges, though substantial, are not daunting given the strength of the national economy. While recent policy measures suggest that the government is taking these challenges seriously, more remains to be done. The associated growth dividend is well worth pursuing. A continental perspective The Africa Infrastructure Country Diagnostic (AICD) has gathered and analyzed extensive data on infrastructure in more than 40 Sub-Saharan countries, including Nigeria. The results have been presented in reports covering different areas of infrastructure (ICT, irrigation, power, transport, water and sanitation) and policy (including investment needs, fiscal costs, and sector performance). This report presents key AICD findings for Nigeria, with the aim of benchmarking the country’s infrastructure conditions against those of its African peers. Two peer groups are considered in the analysis of Nigeria’s performance: (i) resource-rich, low-income countries and (ii) middle-income countries. Where possible and relevant, Nigeria’s performance is compared with that of countries in other developing regions, such as Asia. Detailed comparisons will also be made with immediate neighbors in the Economic Community of West African States (ECOWAS). Several methodological issues should be borne in mind. First, because of the cross-country nature of data collection, a time lag is inevitable. The period covered by the AICD runs from 2001 to 2006. Most technical data presented are for 2006 (or the most recent year available), while financial data are typically averaged over the available period to smooth out the effects of short-term fluctuations. Second, when making comparisons across countries, we had to standardize the indicators and analyses to ensure their correspondence. This means that some of the indicators presented here may be slightly different from those that are routinely reported and discussed at the country level. 2 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE Why infrastructure matters As in the rest of the continent, West Africa’s growth performance improved markedly between the 1990s and 2000s. The overall improvement in per capita growth rates has been estimated at just under 2 percentage points, of which 1.1 percent is attributable to better structural policies and 0.9 percent to improved infrastructure. During the decade 1998–2008, Nigeria’s economy grew at an average annual rate of over 5 percent. Improvements in infrastructure added 1 percentage point to Nigeria’s per capita growth rate for the period 2003 to 2007 (figure 1a). Interestingly, the impact was not as large as in neighboring West African countries such as Benin, Côte d’Ivoire, and Senegal. We should note that the boost to Nigeria’s growth came almost exclusively from the ICT revolution. Meanwhile, Nigeria’s power sector held the per capita growth rate back by 0.13 percentage points over the same period. Raising Nigeria’s infrastructure to the level of the African leader, Mauritius, would boost annual per capita growth rates by 4 percentage points, according to simulations. About half of this potential impact is associated with improvements in the power sector, which would contribute as much as 2 percentage points to the per capita growth rate (figure 1b). Overall, evidence from enterprise surveys suggests that infrastructure constraints are responsible for about 40 percent of the productivity handicap faced by African firms. Figure 1. Infrastructure has contributed much to economic growth—but could contribute more a. Infrastructure’s contribution to annual per capita economic growth in select countries, 2003–07, in percentage points 2.5 2.0 1.5 1.0 0.5 0.0 -0.5 -1.0 telecom electricity roads 3 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE b. Potential contribution of infrastructure to annual per capita economic growth in select countries, in percentage points 5.0 4.0 3.0 2.0 1.0 0.0 -1.0 -2.0 telecom electricity roads Source: Calderón 2009. The state of Nigeria’s infrastructure The spatial distribution of Nigeria’s economy shows marked differences between north and south. The south is characterized by relatively high population density, and this is where many of the country’s cities and larger towns are clustered (figure 2a, b). Meanwhile, there is an important concentration of both population and agricultural activity in the north of the country (figure 2a, c). What is particularly striking is how rapidly the incidence of poverty rises with distance from the coast. While poverty rates in the coastal states are typically under 40 percent, they rise above 70 percent in many parts of central Nigeria and particularly in the far north (figure 2b). Relative to other African countries, the development of agriculture is pronounced: there are relatively few areas of agricultural potential that are not already being tapped (figure 2d). This is true across the national territory and is particularly so in the north. The bulk of the national territory lies squarely in the Niger River basin, which is shared by a number of neighboring countries (figure 2c). Although Nigeria’s infrastructure networks mirror the spatial concentration of economic activity in the south, the country (unlike some of its neighbors) has developed infrastructure backbones that are national in reach (figures 3a–d). Few areas remain unconnected to national backbones, and those few are generally concentrated in the central west and east of the country (figures 3a–d). That said, road network conditions are quite patchy, adversely affecting national connectivity. The conditions of many key routes alternate between good, fair, and poor across different sections (figure 3a). The national power transmission network is national; almost all major generation assets are on the interconnected system. While the global system for mobile communications (GSM) coverage is widespread, coverage gaps are more prevalent in the northern part of the country (figure 3c). Despite high levels of agricultural activity, irrigated areas are very limited and mainly flank river corridors, particularly in the north and northeast (figure 3d). 4 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE In terms of regional integration, the picture is mixed. Nigeria is connected to the South Atlantic 3 (SAT-3), MAIN-1, and Glo-1 submarine cables skirting the west coast of Africa, but lacks fiber-optic land links with its neighbors (figure 3c). There are five points where Nigeria’s national road network intersects with the regional one: the east-west coastal routes and a handful of corridors to the landlocked hinterland. As far as power is concerned, there is the longstanding interconnector with Niger, to the north; there are plans to interconnect with Benin and Niger in the context of the West Africa Power Pool (WAPP); but there is no interconnection with Cameroon, to the east. The West Africa Gas Pipeline links Ghana to Nigeria and allows the export of gas for power generation. Table 1. Achievements and challenges in Nigeria’s infrastructure sectors Achievements Challenges Air transport Recent expansion of domestic market Developing potential as regional air transport hub Emergence of important regional carriers New routes to Europe and the United Concessioning of airport terminals States Significant improvements in safety oversight ICT Extensive low-cost GSM coverage Increasing penetration of ICT services Vibrant competitive fixed-line sector Reducing cost of Internet services Extensive private fiber-optic backbones Addressing market-efficiency gap Ports Adoption of modern landlord model Improving customs performance Award of numerous concessions Improving land and marine access Planning for new capacity additions Power High rates of electrification Investing to improve service reliability Sector restructuring and tariff hikes in Addressing huge sector inefficiencies progress Railways Extensive national rail network Improving performance to recapture traffic Roads Extensive national road network Increasing funding for road maintenance Improving rural access Water resources Progress on institutional framework Developing huge high-return irrigation potential Water and sanitation Improving access to improved water services Reversing growth in open defecation Addressing utilities’ huge inefficiencies Paying greater policy attention to wells and boreholes Improving quality of traditional latrines Source: Authors’ elaboration of AICD findings. Note: ICT = information and communications technology; GSM = global system for mobile communications. In this report we begin by reviewing the main achievements and challenges in each of Nigeria’s major infrastructure sectors (key findings are summarized in table 1). Thereafter, attention will turn to the problem of financing Nigeria’s outstanding infrastructure needs. 5 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE Figure 2. Nigeria’s population density tracks agricultural activity in the north and south, with wealth concentrated near the urbanized coastal strip a. Population 6 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE b. Poverty 7 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE c. Topography 8 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE d. Natural resources Source: AICD Interactive Infrastructure Atlas for Ghana (http://www.infrastructureafrica.org/aicd/system/files/gha_new_ALL.pdf). 9 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE Figure 3. Nigeria’s infrastructure networks cover its national territory extensively a. Roads b. Power 10 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE c. ICT d. Water Source: AICD Interactive Infrastructure Atlas for Ghana (http://www.infrastructureafrica.org/aicd/system/files/gha_new_ALL.pdf). Note: ICT = information and communications technology. 11 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE Roads Achievements Nigeria has developed an extensive national road network. Both paved and unpaved road network densities are more than twice as high as those for the peer group of resource-rich African countries, although still only half of the levels found in Africa’s middle-income countries. Traffic volumes on Nigeria’s paved and unpaved networks are also relatively high compared with those of similar countries, and indicate that networks are being utilized. Table 2. Nigeria’s road indicators benchmarked against Africa’s low- and middle-income countries, 2006 Unit Resource- Nigeria Middle-income rich countries countries Paved road density km/1000 km2 of arable land 59.1 174.1 318.4 Unpaved road density km/1000 km2 of arable land 38.0 94.2 278.4 GIS rural accessibility % of rural population within 2 km of all-season road 26.0 19.7 31.5 Paved road traffic Average annual daily traffic 1,408.2 1,772.4 2,558.3 Unpaved road traffic Average annual daily traffic 24.7 32.7 74.7 Paved network condition % in good or fair condition 67.9 67.4 82.0 Unpaved network condition % in good or fair condition 61.4 32.9 57.6 Perceived transport quality % firms identifying roads as major business constraint 30.2 29.9 18.2 Overengineering % paved network with <300 vehicles per day 19.8 4.8 18.4 Underengineering % unpaved network with >300 vehicles per day 9.3 26.7 20.0 Source: Gwillliam and others 2009. Derived from the AICD national database (http://www.infrastructureafrica.org/aicd/tools/data). Note: GIS = geographic information system. Challenges Nigeria has established a federal road maintenance agency (FERMA) as a stopgap before undertaking more substantive sector reforms, but continues to rely on traditional budget allocations to fund road maintenance and rehabilitation. In recent years a substantial number of African countries have taken measures to establish road-user charges or fuel levies of various kinds. These feed into a ring-fenced road fund, with the aim of providing a stable source of revenue for road maintenance. In many cases, the establishment of a road fund has been accompanied by the creation of a road agency, an autonomous entity charged with the implementation of road maintenance and rehabilitation works. In Nigeria’s case, FERMA is responsible for the federal (or primary) network, but continues to rely on general budget resources for the funding of road maintenance. Its governance structures and procedures (human resource management, operational decision making, and so on) are still overshadowed by public service norms, presenting an obstacle to institutional independence, efficiency, and accountability. Considering these issues, the current arrangement would require review even if adequate funds for road maintenance were being secured through the budgetary process. Sadly, however, road maintenance remains underfunded. Nigeria has been allocating ample resources to federal road rehabilitation, but does not appear to have reserved enough of these resources for preventive maintenance (figure 4). In the years between 2001 and 2006, Nigeria spent just over $700 million on the federal network per year. Network simulations indicate that a yearly budget of around $580 million should be adequate both to maintain the federal network and 12 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE to complete pending rehabilitation works within a five-year horizon. Higher spending may simply indicate a more accelerated rehabilitation program, or relatively high unit costs; in any case, recent spending levels are nearing the right levels. The problem lies in the fact that only $50 million per year has been allocated to preventive maintenance, compared to a benchmark requirement of $240 million. The amount currently being allocated to maintenance is just about adequate for routine maintenance, but does not cover periodic, preventive activities. Thus, while the overall allocation is adequate, there appears to be a marked bias toward capital expenditure. This finding is borne out by the fact that only 75 percent of the federal network is in good or fair condition. Problems of road maintenance are apparently much more severe at the subnational level. Road condition indicators for the entire national network are much worse than for the federal network (table 2). Only 67 percent of paved roads are in good or fair condition. Even more worrisome is the fact that only 33 percent of unpaved roads are in good or fair condition. These indicators are themselves evidence that maintenance activities are not being adequately funded or implemented at the subnational level. While it was not possible to collect data on subnational road maintenance expenditures, estimates suggest that the annual maintenance and rehabilitation requirement for the subnational network is around $500 million, or approximately the same as that for the federal network. Rural accessibility remains a serious problem in Nigeria, with major repercussions for agricultural and rural development. As already noted, the country’s unpaved roads are in particularly poor condition. Furthermore, there is evidence of substantial underengineering in the unpaved network, of which a quarter is above the economic traffic threshold usually used to justify the paving process (table 2). The evidence on rural access levels is somewhat conflicting. According to household survey evidence, about 47 percent of rural inhabitants live within 2 kilometers (km) of an all-season road. This is well above the average of around 34 percent for Sub-Saharan Africa, but still falls well short of the 67 percent average found in other developing countries. On the other hand, geographic information system (GIS) analysis suggests that only about 20 percent of rural Nigerians have access to an all-season road, a figure somewhat below the average for the peer group. (The survey and GIS analysis should not be expected to give consistent answers, each having its own limitations.) In any case, it is clear that Nigeria’s rural road network falls well short of what is needed to service the rural economy. Realistic extension of rural access will require strategic alignment of road and agricultural development policies. Nigeria’s classified road network amounts to 85,000 km. To provide all-season road coverage to just 75 percent of the rural population would require the classified network to be extended by a further 20,000 km—a tall order. Nevertheless, if rural road development were to be closely aligned with agricultural priorities, a fully functional classified network of just 50,000 km would be adequate to provide connectivity to areas producing 80 percent of the country’s agricultural output by value. 13 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE Figure 4. Nigeria’s spending falls substantially short of maintenance needs, 2006 100 Spending as % of requirements 80 60 40 20 0 -20 -40 -60 -80 -100 maintenance rehabilitation Source: Gwillliam and others 2009. Note: * Analysis of the adequacy of road-maintenance spending can be performed for only the primary network under federal jurisdiction. Rail Achievements Nigeria has one of the most extensive national rail networks in Africa, second only to South Africa in length. Rail lines run to the northwest, northeast, southwest, and southeast of the country. Historically, Nigeria’s railway was among the best in West Africa, but it has since fallen into neglect. Challenges Despite Nigeria’s potentially significant demand for rail, traffic volumes have all but collapsed— much more so than in many other African countries. Nigeria’s large population and economy create substantial demand for intercity passenger traffic as well as freight movements. But due to deficient performance and erratic service, traffic volumes have been on a long-term decline from 3 million tonnes in 1960 to 15,000 in 2005—equivalent to about five trucks per day. Similarly, passenger traffic has declined from 3 million to 500,000 passengers per year over the same period—equivalent to about 25 buses per day. As of today, traffic density—at only 15,000 tonnes per kilometer (tonne-kms)—is a tiny fraction of the already-low levels found on other African railways. 14 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE Table 3. Railway indicators for Nigeria and select countries, 2006 TRANSRAIL (Senegal—Mali) SPOORNET (South Africa) (Côte d’Ivoire—Burkina Faso) CAMRAIL (Cameroon) NRC (Nigeria) OCBN (Benin) GRC (Ghana) SITARAIL Concessioned (1)/ state run (0) 1 1 0 1 1 1 0 Traffic density, freight, 1,000 tonne-km/km 15 242 148 494 318 1,091 5,319 Efficiency Staff: 1,000 UT per staff 37 84 40 481 603 3,037 Coaches: 1,000 passenger-km per coach 737 416 900 862 4,738 596 Cars: 1,000 tonne-km per wagon 59 458 74 1,020 804 868 925 Locomotive availability in % 13 7 3 35 40 26 — Tariffs Average unit tariff, freight, US cents/tonne-km — 2.4 2.0 3.3 2.2 2.2 — Average unit tariff, passenger, US cents/passenger-km — 4.4 5.8 5.5 3.3 5.2 — Source: Bullock 2009. Derived from the AICD rail operator database (http://www.infrastructureafrica.org/aicd/tools/data). Note: UT = unit tariff. — = Not available. Ports Achievements Nigeria’s port system has traditionally put a brake on economic development, due to poor performance and high costs. As of 2006, the performance parameters for Nigeria’s major ports were very poor by global and even African standards (table 4). The global benchmark for container dwell time was around 7 days, compared with 30 to 40 days in major Nigerian ports at that time. Similarly, for truck cycle time, global best practice is on the order of one hour, compared with around one day in some of Nigeria’s major ports. And for container crane productivity, the figure for Apapa in 2006 was 12 moves per hour compared to 25–30 moves internationally. Meanwhile, for general-cargo crane productivity, the figure was 8–9 tonnes per hour (tonnes/hr) for the major Nigerian ports compared to 30 tonnes/hr internationally. 15 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE Table 4. Benchmarking port indicators for Nigeria and select countries, 2006 Cotonneou (Benin) Apapa (Nigeria) Dakar (Senegal) Onne (Nigeria) Tema (Ghana) Durban (South Port Harcourt Abidjan (Côte (Nigeria) d’Ivoire) Africa) Capacity Actual containers handled (‘000sTEU/year) 336 8 86 500 158 420 331 1,899 Container-handling capacity (‘000sTEU/year) 500 — 100 — — 375 — 1,450 Actual general cargo handled (‘000s tonnes/year) 3,379 882 1,630 General-cargo-handling capacity (tonnes/year) 5,000 2,000 4,000 n.a. 2,500 8,500 — — Efficiency Average container dwell time in terminal (days) 42 30 30 12 12 25 7 4 Average truck-processing time for receipt and delivery of cargo (hours) 6 24 24 2.5 6 8 5 5 General cargo vessel preberth waiting time (hours) 36 38 6 2.9 48 9.6 24 — General cargo vessel turnaround time (hours) — 46 38 2.2 48 48 60 — Average container crane productivity (containers loaded/unloaded per crane working hour) 12 — — 18 13 — 15 Average general cargo crane productivity (tonnes loaded/unloaded per crane working hour) 9 8 8 16 15 13.5 — 25 Tariffs Average container-handling charge, ship to gate ($/TEU) 155 — 145 260 180 168 160 258 Average general-cargo-handling charge, ship to gate ($/tonne) 8.0 8.0 6.5 13.5 8.5 10.0 15.0 8.4 Average dry-bulk-handling charge, ship to gate or rail ($/tonne) ─ ─ ─ 5.0 5.0 3.0 5.0 1.4 Average liquid-bulk-handling charge, ship to gate or rail ($/tonne) 1.0 1.0 — ─ ─ 1.5 4.0 ─ Source: Ocean Shipping Consultants 2009. Derived from the AICD ports database (http://www.infrastructureafrica.org/aicd/tools/data). Note: TEU = 20-foot equivalent unit. — = Not available. n.a. = Not applicable. A comprehensive reform of the port sector began in the year 2000. It was designed to remove the major impediments to efficient operation and thereby facilitate streamlined import and export activities. Nigeria’s port sector reform program was wide ranging, detailed, and implemented on a scale unprecedented for this sector in Africa. The reforms undertaken were well planned, for the most part well implemented, and placed the country’s port system on a much more sound footing. They included a shift of management toward the landlord port model and the extensive award of private sector concessions for frontline cargo-handling facilities. To fit the landlord model, the Nigerian Ports Authority (NPA) has been extensively restructured. This includes its decentralization into four new autonomous port authorities: Lagos, Calabar, Port Harcourt, and Delta. Under the new structure, the NPA’s key functions were defined as planning and developing port infrastructure, facilitating the financing of new construction through build-operate-transfer (BOT) 16 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE arrangements, licensing private operators to provide port services, collecting port authority tariffs, and generally acting as a landlord on behalf of the federal government. Furthermore, extensive provisions were made for the retrenchment of human resources in case of overstaffing. At the same time, a comprehensive program of concessions for key cargo terminals, including container-terminal facilities, was implemented. In all, 25 concessions were identified among the 11 ports under the NPA’s control. The concessions awarded in 2005–06 have raised as much as $716 million for capital investment in the sector—more than half of the cumulative total of private port financing ever raised in Sub-Saharan Africa. Challenges Despite the important progress made by Nigeria’s port sector reforms, a number of key challenges remain (see box 1 for the example of Apapa). Box 1. Impact of reforms at Lagos’s Apapa port The Lagos port has long been notorious for inadequate facilities and congestion. As part of a broader program of port reform, in early 2006 the Nigerian Ports Authority (NPA) awarded a concession to APM Terminals to manage, operate, and develop the Apapa container terminal, increasing capacity from 220,000 TEUs per year to 1.6 million TEUs. Within months of the award of that concession, berthing space delays dwindled significantly, and shipping lines reduced their congestion surcharge from €525 to €75 per TEU, saving the Nigerian economy $200 million a year. By early 2009, new gantry cranes had been acquired to triple the original capacity. But that was not the end of the story. Although the port’s equipment was able to process more than 500 containers per day for customs examinations, the majority of containers were returned to stacking by the end of each day. By January 2009, the port was clogged by uncollected containers, and at the end of February, the head of the NPA announced a temporary suspension of ship entry with immediate effect, lasting until mid-April, to enable terminals to clear ―alarming‖ backlogs. The controller of the Nigeria Customs Service for Apapa blamed the low clearance volume on the need to physically examine every container due to the high incidence of concealment and false declaration by importers. But even cleared containers were not being collected. At the end of January, of the reported 9,741 containers waiting in the port for delivery to importers, 851 had been cleared by customs with all charges paid and documentation completed but had not been picked up by agents. The NPA consequently proposed introducing demurrage charges of 680 naira per TEU in a bid to force owners to move their containers out of the ports. In turn, however, many agents blamed a lack of trucks, arguing that the number needed to empty containers exceeded current supply. Although the moratorium on entry of new vessels was lifted in early March, some backlogs and delays and significant organizational and regulatory problems remained. Source: Foster and Briceño-Garmendia 2009: chapter 12. Note: TEU = 20-foot equivalent unit. The reforms have not managed to circumvent some of the broader-based problems that negatively impact the port system, such as poor customs performance and corruption. For example, the Onne port actually had to close at one point due to the slow clearance of cargo by customs. There is also the need to improve both marine and landside access to port, as well as to plan for new capacity infrastructure (particularly at Lagos’s Apapa port). In this context, there is a clear need for detailed long-term planning, to be headed by the NPA in its new landlord role. There have also been recent complaints about rising cargo-handling costs. 17 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE Air transport Achievements Nigeria’s air transport market tripled in size between 2004 and 2007, largely due to the rapid expansion of domestic services. The number of seats serving the Nigerian market was almost stable, at around 4 million a year over the period 2001 to 2004, but mushroomed thereafter to reach over 12 million annually by 2007. This growth was driven almost entirely by a dramatic expansion in the domestic air transport market. Among its Sub-Saharan peers, the size of Nigeria’s market is second only to South Africa. Moreover, with a Herfindahl index1 of 18 percent, Nigeria’s domestic air transport market is much more competitive than that of most other countries in the region. Figure 5. Nigeria’s domestic air traffic has mushroomed in recent years 14 Estimated annual air-transport 12 10 seats (millions) 8 6 4 2 - 2001 2004 2007 domestic international intercontinental total Source: Gwillliam and others 2009. Some of Nigeria’s private carriers have also become major players regionally. As of 2001, the regional air transport market in West Africa was dominated by three carriers—Air Afrique, Ghana Airways, and SN Brussels—that together accounted for 54 percent of the market. Following the demise of Air Afrique and Ghana Airways, as well as Nigeria Airways itself, there was a major shift in the regional air transport market. Three new players—Air Senegal, Virgin Nigeria, and Bellview Airlines—have emerged, accounting for 44 percent of the regional market. Virgin Nigeria and Bellview Airlines were both privately owned registered operators that each held a roughly 11 percent share of the regional market. Virgin Nigeria’s share continued to grow, until by 2007 it had over 50 percent of the seat capacity in the West African air transport market (taking both domestic and intraregional flights into account). But a major shift occurred when Bellview ceased operations in 2009, and Virgin decided to sell its 49 percent stake in Virgin Nigeria (the airline went on to rebrand itself as Air Nigeria in September 2009). In the meantime, Arik Air rapidly rose to prominence with a broadened domestic network and new destinations that include Johannesburg, London, and New York. 1 The Herfindahl index, a measure of market concentration, is computed by summing the squares of the market share of each market participant. 18 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE Nigeria is one of the few countries in Africa whose safety standards support direct flights to the United States. In August 2010 Nigeria became one of the few countries in Sub-Saharan Africa (Cape Verde, Ethiopia, and South Africa) whose safety oversight is considered good enough for the United States to allow direct flights by Nigerian carriers from Nigeria to the United States. By passing the U.S. Federal Aviation Administration (FAA) International Aviation Safety Assessment (IASA) program audit, Nigeria proved itself after a deliberate and determined effort. A string of fatal accidents between 2005 and 2006 had prompted the government to demand all airlines in Nigeria to recapitalize and reregister themselves to obtain a valid operating certificate. Challenges While traffic has mushroomed, connectivity has remained largely unchanged, and remains limited within ECOWAS. As of 2007 Nigeria’s network consisted of some 20 domestic city pairs and 50 international city pairs. In terms of intraregional connectivity within the ECOWAS, by far the best-served route is between Lagos and Accra, with 44 flights per week in 2010. Among domestic pairs, Abuja/Lagos registered 208 flights per week in 2010. Thereafter, connectivity drops off markedly: both Bamako/Abidjan and Accra/Abidjan registered 17 flights per week. No other regional destination comes close to having a daily service, which is striking given that Nigeria is a major regional player. Lagos has not yet assumed its place as an air transport hub for the region. On the eastern and southern side of the continent, a strong hub-and-spoke structure has developed around Johannesburg, Nairobi, and Addis Ababa. By contrast, a functioning hub system is conspicuously absent in West Africa. Due to its size and location, an airport such as Lagos has the potential to play such a role, one that it has not yet fulfilled, mainly because the Federal Airport Authority of Nigeria has not been reformed and has not been allowed to proceed with the private sector concessioning of key airport terminals in dire need of investment, such as Lagos International Terminal II. Intense competition may herald further industry consolidation. Nigeria’s aviation industry now boasts the most modern aircraft fleet in the region and has the only regional carrier offering wide-body aircraft services (for example, Arik’s Airbus A340 and 330). Meanwhile, a rapid increase in seat supply has exerted downward pressure on domestic fares within Nigeria and, in a highly leveraged industry, is likely to result in some much-needed consolidation. Table 5. Benchmarking air transport indicators for Nigeria and other select countries, 2007 Côte Country Nigeria Ghana Senegal Kenya Tanzania d’Ivoire Traffic (2007) Domestic seats (millions per year) 9.30 0.14 0 0.13 2.09 1.87 Seats for international travel within Africa (millions per year) 1.37 0.91 0.85 1.26 3.14 1.27 Seats for intercontinental travel (millions per year) 2.44 0.83 0.30 1.23 2.76 0.59 Seats available per capita 0.09 0.08 0.06 0.23 0.28 0.12 Herfindahl Index—domestic market (%) 18.0 100.0 — 100.0 60.5 31.0 Herfindahl Index—international market 6.4 6.4 9.8 10.3 34.1 13.0 19 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE Quality Percent of seat-km in medium or smaller aircraft 29.6 15.7 52.3 39.3 23.3 48.6 Percent of seat-km in newer aircraft 71.4 96.8 90.8 98.3 80.2 79.3 Registered carriers on EU blacklist 0 0 0 0 0 0 FAA/IASA audit status No audit Fail Fail No audit No audit No audit Percent of carriers passing IATA/IOSA audit 28.6 0 0 50.0 11.1 33.3 Source: Bofinger 2009. Derived from the AICD national database (http://www.infrastructureafrica.org/aicd/tools/data). Note: EU = European Union; FAA = U.S. Federal Aviation Administration; IASA = International Aviation Safety Assessment; IATA = International Air Transport Association; IOSA = IATA International Safety Audit. — = Not available. Water supply and sanitation Achievements Nigeria’s performance in sanitation is somewhat better than that of the resource-rich country peer group. Access to flush toilets, at 23 percent, is twice the average for resource-rich countries in Africa, even if still half that in middle-income countries. More than one-third of Nigerians rely on improved latrines as their main source of sanitation, a level comparable to other resource-rich countries. Access to traditional latrines, at 13 percent of the population, is below the level of resource-rich countries. But one in three Nigerians continues to practice open defecation (table 6). Challenges The practice of open defecation continues to increase, and little net progress is being made toward improving sanitation overall. In 1998, 24 percent of the population practiced open defecation; within 10 years this had increased to 29 percent. Progress with higher-end modalities is mixed. Although the expansion of septic tanks has been significant, it has been largely offset by the decline in both improved and traditional latrines. Whereas about 1.3 percent of the population gained access to septic tanks between 2003 and 2008, about 1.2 and 0.3 percent of the population lost access to improved and traditional latrines, respectively, each year. The use of septic tanks also looks low relative to annual population growth, at 2.4 percent per year (figure 6b). Meanwhile, around 2.3 percent of the population fell into the practice of open defecation during the same period. Relative to its neighbors, Nigeria’s water performance scores are significantly worse than its sanitation. According to the Demographic and Health Survey (DHS) 2008, only 5 percent of the population have access to a private tap and only 8 percent to a public standpost (table 6). By contrast, about 12 percent of the population have access to each of these modalities in Africa’s resource-rich countries, and in Africa’s middle-income countries more than 60 percent have access to piped water. By far the most important sources of water are wells and boreholes, which serve 63 percent of Nigeria’s population. But as many as one in four Nigerians continue to rely on surface water, without access to any better alternative. Particularly worrying is a decrease in access to utility water. By comparing results from successive DHS surveys between 2003 and 2008, it is possible to estimate the rate at which different types of 20 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE services are expanding (figure 6a). During this period, the percentage of the population with access to utility water—whether through private taps or standposts—was actually declining, by around 0.4 percentage points each year. By contrast, more than 3 percent of the population each year has been gaining access to wells and boreholes, making this by far the fastest-growing source of water supply in Nigeria. A particularly positive finding is that the percentage of the population relying on surface water has been on the decline, with 0.4 percent of the population moving away from this unsafe practice every year. Figure 6. Rural access to water and sanitation versus population growth, 2008–08 Share of population gaining access per year a. Water b. Sanitation Population gaining access per year (%) 5 Population gaining access per year (%) 5 4 3.9 4 3.9 3 3 2.4 2.4 2 2 1 1.0 1 1.0 0 0 -1 -1 -2 -2 -3 -3 National Urban Rural National Urban Rural surface water wells/boreholes open defecation traditional latrines standposts piped water improved latrines flush toilets annualized growth annualized growth Source: WHO (2010), from the DHS (2003 and 2008). 21 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE Table 6. Benchmarking water and sanitation indicators Resource- Middle-income Unit Nigeria rich countries countries Mid-2000s 1999 2003 2008 Mid-2000s Access to piped water % pop 12.5 12 8 5 61.1 Access to standposts % pop 12.4 16 11 8 22.1 Access to wells/boreholes % pop 47.0 45 53 63 4.8 Access to surface water % pop 26.6 27 28 22 10.9 Access to septic tanks % pop 12.9 15 16 23 47.7 Access to improved latrines % pop 37.0 42 46 35 33.7 Access to traditional latrines % pop 21.5 17 16 13 6.9 Open defecation % pop 28.3 24 22 29 11.0 2005 Domestic water consumption liter/capita/day 115.0 109 194.8 Revenue collection % sales 60.1 44 99.3 Distribution losses % production 39.7 59 26.2 Cost recovery % total costs 67.1 62 86.3 Operating cost recovery % operating costs 94.0 180 120.8 connections per Labor costs 96.4 57 203.4 employee Total hidden costs as % of revenue % 193 291 67 Scarce water Other developing Nigeria resources regions U.S. cents per m3 2005 Average effective tariff 0.38 60–120 3.0–60.0 Source: AICD water and sanitation utilities database (http://www.infrastructureafrica.org/aicd/tools/data); access figures from DHS (1999, 2003, and 2008). 22 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE Access to utility water is inequitable. Figure 7. Access to water sources is highly inequitable Access to various types of water supply is strongly correlated with household 100 % of population purchasing power. Access to utility water, in particular, is almost nonexistent at the 50 bottom half of the income distribution, and strongly skewed toward higher-income households. But even among these, access to 0 utility water is far from universal, reaching at Q1 Q2 Q3 Q4 Q5 best 20 percent of this group. Thus, even those able to pay for piped water are unlikely piped water standposts to have access. Particularly striking is the wells/boreholes surface water fact that access to standposts is just as Source: Banerjee and others 2009, based on DHS 2003. inequitable as access to private taps, even Note: Q1—first budget quintile, Q2—second budget quintile, and so on. though standposts supposedly represent a lower-cost option for the poor. Access to wells and boreholes, on the other hand, is much more equitable and reaches over half of the population, across the socioeconomic spectrum. As is to be expected, reliance on surface water is heavily concentrated among the poor (figure 7). Access to improved water is much higher in urban than in rural areas. Access to improved water in urban areas is 75 percent, versus 45 percent in rural areas (figure 8a). The main reasons behind this are the higher prevalence of surface water dependence in rural areas, and the fact that 21 percent of the wells and springs in rural areas are unprotected versus only 6 percent in urban areas. Figure 8. Access to water sources is highly inequitable across urban and rural communities a. Water supply b. Sanitation 100 100 90 90 80 80 % of population % of population 70 70 60 60 50 50 40 40 30 30 20 20 10 10 0 0 urban rural urban Rural Source: AICD water supply and sanitation utilities database (http://www.infrastructureafrica.org/aicd/tools/data); access figures calculated 23 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE by AICD using data from the 2008 DHS Survey published by the JMP in March 2010. Nigeria’s water utilities suffer high levels of inefficiency, both in absolute terms and relative to their neighbors. Available data on the performance of Nigeria’s water utilities are limited. Although Nigeria has as many as 36 state water utilities, it was possible to obtain reasonably sound data for only a handful of them—Borno, the Federal Capital Territory, Kaduna, Katsina, Lagos, and Platea—at a single point in time in 2005. These data were later complemented with data for Nasarawa from the IbNet database. Together these utilities serve a substantial customer base of 25 million people, comprising about half of the urban population of Nigeria. The indicators presented are a weighted average for this sample (table 7). They indicate that the Nigerian utilities perform as poorly, and in some areas worse, than utilities in the resource-rich peer group. In particular, performance on revenue collection and labor productivity is substantially worse than the peer group. Revenue collection is as low as 44 percent of billed amounts, and labor productivity—at 57 connections per employee—is just a quarter that of a well-performing utility in Africa. Distribution losses, at 59 percent, are also substantially worse than the 39 percent reported for the peer group. Cost-recovery tariffs for water appear to be perfectly affordable for those enjoying access today. The average effective residential tariff, at just under $0.38 per cubic meter (m3), more than covers average operating costs of around $0.21/m3, but falls significantly short of the estimated $0.61 cost-recovery level (table 7). This raises the important question of whether cost-recovery tariffs would be affordable to utility customers. Considering subsistence consumption of 4 m3/month—which amounts to an absolutely minimal consumption of 25 liters per capita per day for a family of five—a monthly water bill charged at cost-recovery tariffs would be $3.20. With a somewhat more generous definition of subsistence consumption of around 10 m3/month, the cost of a monthly water bill charged at cost-recovery tariffs would be $8.00. Based on an affordability threshold of 5 percent of the household budget, and looking at the distribution of purchasing power across Nigeria’s households, a monthly bill of $3.20 would be affordable to 95 percent of the population, while a bill of $8.00 would be affordable to 60 percent of the population (figure 7). Given that, as of today, access to water is confined to less than 10 percent of the population at the high end of distribution, there do not appear to be any significant problems in the affordability for cost-recovery tariffs. Nor would such problems arise until access to piped water had expanded significantly, to reach about 50 percent of the population. Table 7. Operational indicators associated with select Nigerian utilities, as of 2005 Water System losses Collection Average total Average Total hidden Total hidden delivered ratio cost effective tariff costs costs Utility (million (%) (%) (US$/m3) (US$/m3) (US$ (% revenues ) m3/year) millions/year) FCT 86 80 20 0.66 0.43 18 130 Kaduna 81 58 86 0.53 0.21 20 322 Katsina 36 30 23 0.56 0.33 14 743 Lagos 116 57 41 0.66 0.46 39 413 Nasarawa 10 32 25 0.48 0.44 3 414 Nigeria 330 59 44 0.61 0.38 95 291 Source: Derived from Briceño-Garmendia, Smits, and Foster (2009). Note: For Nigeria water delivered (million m3/year) and total hidden costs (US$/year) are reported as the sum of the utilities; the other indicators are calculated as weighted averages. 24 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE By comparing Nigerian utilities with well-performing benchmarks, it is possible to quantify the hidden costs that arise from these inefficiencies. Here three types of such costs are considered: first, those associated with distribution losses in excess of the good-practice benchmark of 20 percent of production; second, those associated with revenue collection that falls short of the 100 percent best-practice benchmark; and, third, any shortfall in the average effective tariff relative to what is needed to fully recover operating and capital costs. The hidden costs of Nigerian water utilities look to be among the highest in the region. The combined effects of underpricing, overstaffing, undercollection, and distribution losses imply a sizeable financial hemorrhage. In the case of the Nigerian utilities sampled, the value of these hidden costs is estimated to be almost three times as great as the utilities’ turnover. In the worst-performing utility of the sample (Katsina), the hidden costs are seven times as large as the utility’s turnover. Even for the most efficient of the sample utilities (FCT), hidden costs are still worse than those among other utilities in West Africa (figure 9). Figure 9. Hidden costs of select water utilities, as percentage of revenues Katsina Nasarawa Lagos Kaduna Federal Capital… Nigeria Average (2005) Mali Liberia Burkina Faso Niger Côte d'Ivoire Ghana Benin Senegal 0 200 400 600 800 % of revenues unaccounted losses underpricing collection inefficiencies Source: Derived from Banerjee and others (2008b) and Briceño-Garmendia, Smits, and Foster (2009). While improving utility performance will be a key to expanding access, more attention needs to be given to those alternatives that are most widely used. In the medium term, Nigeria needs to work hard to provide more of its population with access to utility services for water and sanitation. To this end, addressing the performance deficiencies of service providers is key. Nevertheless, it is important to recognize that for the foreseeable future the bulk of Nigeria’s population will continue to rely on boreholes for water and traditional latrines for sanitation services. Policy makers therefore need to give some attention to ways of improving the quality and effectiveness of these basic services. In the case of 25 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE boreholes, there are many policy issues surrounding their unregulated and uncoordinated use. In the case of traditional latrines, policy makers should promote the use of better design and building techniques among artisans. Furthermore, there are potential health issues that arise when groundwater and low-grade in situ sanitation are found in close proximity in urban areas. Power Achievements Nigeria has achieved relatively high rates of electrification, particularly in urban areas, and access is expanding rapidly. As of 2003, Nigeria had electrified over 50 percent of its population, just slightly ahead of the peer group of resource-rich countries (table 8). Power coverage in urban areas, at 84 percent, was well ahead of the resource-rich peer group, and on par with Africa’s middle-income countries. Even rural electrification, at almost 35 percent, represents strong performance. Not only does Nigeria have high access to power, but electrification expanded relatively rapidly between the mid-1990s and the mid- 2000s. The pace of electrification seems to have slowed subsequently. Challenges Despite high levels of electrification, Nigeria’s power sector has struggled to provide an adequate supply of reliable power. The country’s installed power capacity, at around 42 megawatts (MW) per million people, is typical of the resource-rich peer group (table 7), but it is only about 5 percent of the installed capacity of 800 MW per million people found in Africa’s middle-income group. Moreover, in Nigeria’s case as much as 35 percent of this capacity is not in functioning order. As a result, the country was able to meet only 67 percent of peak demand as of 2007, and the power system was able to supply only 55 percent of total estimated demand as of 2008. Indeed, electricity generated in 2007 was actually lower than in 2002. As a result, indicators such as generation capacity per million population and power consumption per capita actually deteriorated slightly between the mid- and late 2000s. The economic impacts of Nigeria’s power deficit are substantial. According to enterprise surveys, Nigeria is affected by power outages more than 320 days a year, a level many times higher than that found in other African countries. As a result, the percentage of Nigerian firms owning their own backstop generators is 60 percent, again substantially higher than elsewhere in Africa. Formal private sector revenues lost as a result of power outages come close to 10 percent. If we (very conservatively) estimate the value of lost load as the cost of backstop generation to the private sector (approximately $0.40 per kilowatt-hour, kWh), then the aggregate social cost of power outages in recent years amounts to as much as 3.7 percent of GDP, well beyond levels found in other African countries (figure 10). If the value of lost load is instead estimated with reference to the likely economic losses in production (of easily $1.00 per kWh), then the aggregate social cost of power outages could be two to three times as high. 26 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE Figure 10. Power outages are a major tax on Africa’s economies Economic cost of power outages in select countries Nigeria Malawi Uganda Kenya South Africa Tanzania Madagascar Benin Cabo Verde Senegal Cameroon Burkina Faso 0 1 2 3 4 % of GDP Source: Derived from Eberhard and others (2009). Nigeria’s power sector has been characterized by a high degree of operational inefficiency and underpricing. As of 2005 only 64 percent of billed revenues were collected, compared with 81 percent in the resource-rich peer group (table 6). Distribution losses were as high as 30 percent, compared to best- practice levels of 10 percent. Tariffs covered about 28 percent of the historic costs of power production, on average, compared with over 50 percent for the peer group. Nigeria’s power tariffs are set very low, both by global standards and relative to any relevant cost benchmark. With respect to power pricing, as of 2005, Nigeria’s residential power tariffs, at around $0.03/kWh, were among the lowest in Africa—and well below the average of $0.16/kWh found in African countries predominantly reliant on thermal generation technologies (figure 8). Nigeria’s rates were also well below the range—typically between $0.05 and $0.10 per kWh—found in other parts of the developing world (table 8). According to the Nigerian government, the average total historic cost of producing power in the country has been on the order of $0.15/kWh (22 naira). Looking ahead to 2015, the long-run marginal cost of producing additional power is projected to be slightly lower, at around $0.13/kWh. As a result, Nigeria faces enormous hidden costs in the power sector, by far the worst in Africa. Each of the inefficiencies in the power sector results in hidden costs, which when tallied amount to more than five times the sector turnover (figure 11). In absolute terms, these hidden costs amount to a staggering $3.3 billion annually, equivalent to 2.9 percent of GDP. While substantial hidden costs are typical of African power utilities, the scale of the problem in Nigeria is much higher than anywhere else (figure 12). Following the sector reforms, tariffs have been increasing and sector performance improving. A major reform program initiated in 2005 had significant repercussions for the sector. The reforms led to the horizontal and vertical unbundling of the national power utility into six generating companies, one transmission company, and eleven distribution companies. In August 2010, the Nigerian government issued the Road Map for Power Sector Reform (Presidency 2010) to galvanize the reform process. The road map points to the difficulties ahead if status quo operations are maintained, and recommends removing obstacles to the private sector participation that promises to fill the sector’s large investment 27 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE gaps. Meanwhile, the government set appropriate pricing mechanisms to ensure the financial viability of the public distribution companies and any offtaker in power purchase arrangements. The government also committed to a Multi-Year Tariff Order (MYTO), introduced in 2005, whose initial objective was to gradually raise the power tariff to $0.07/kWh (10 naira) by 2011. The government, however, is currently revising the MYTO to specify an aim of $0.14/kWh (22 naira) over the next 5 to 10 years. Meanwhile, the Nigeria Bulk Electricity Trading Company has been established to act as a ―single buyer‖ purchasing power on behalf of distribution companies and other bulk customers until the sector reaches financial sustainability. The government expects that it will take several years before the benefits of the reforms will effectively transform the sector’s financial performance and creditworthiness. The benefits of the reform process can already be clearly seen in the dramatic reduction of the sector’s hidden costs, even if these remain high in both relative and absolute terms. As a result of the MYTO, the average effective tariff increased from around $0.04/kWh in 2005 to $0.06/kWh in 2009. At the same time, institutional reforms led to significant improvements in operational efficiency. Revenue collection rates increased from 64 to 88 percent, even as system losses fell from 30 to 20 percent (table 9). The overall effect of this was the reduction of hidden costs from 548 percent to 247 percent of sector revenues (figure 11). This led to savings of $1.3 billion annually, or 1.8 percent of GDP. While these gains are very important, there is still a long way to go: Nigeria’s power utilities still present the highest hidden costs of any in West Africa (figure 12), with an equivalent economic value of nearly $2 billion annually, or 1.2 percent of GDP. Table 8. Benchmarking power indicators Unit Resource-rich Nigeria Middle-income countries countries Mid-2000s Late 2000s Installed power generation capacity MW/million people 43.2 41.7 38.1 798.6 Power consumption kWh/capita 205.7 151.9 107.6 4,479.3 Power outages Day/year 14.5 321.0 — 5.9 Firms’ reliance on own generator % consumption 44.9 60.9 — 10.9 Firms’ value lost due to power outages % sales 7.0 8.9 — 1.6 Access to electricity % population 46.0 51.3 48.6 59.9 Urban access to electricity % population 79.4 84.0 85.0 85.2 Rural access to electricity % population 28.0 34.6 31.0 31.8 Growth access to electricity % population/year 2.4 2.8 0.6 1.5 Revenue collection % billing 81.1 63.5 88.0 100.0 Distribution losses % production 25.8 30.0 20.0 10.1 Cost recovery % total cost 53.9 28.0 31.0 100.0 Total hidden costs as % of revenue % 168.3 548.2 246.6 0.1 U.S. cents Nigeria Predominantly Other developing thermal generation regions Mid-2000s Late 2000s Average effective power tariff 4.2 4.7 16.0 5.0–10.0 Source: Eberhard and others 2009; derived from AICD electricity database (http://www.infrastructureafrica.org/aicd/tools/data). 28 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE Note: Mid-2000s data are for 2005 in the case of power sector indicators and 2003 in the case of access figures; late 2000s data are for 2009 in the case of power sector indicators and 2008 in the case of access figures. kWh = kilowatt-hour; MW = megawatts. — = Not available. Table 9. Evolution of hidden costs associated with the national power utility Load System Collection Average total Average effective Total hidden Total hidden served losses ratio cost tariff costs costs (GWh/year) (%) (%) (US$/kWh) (US$/kWh) (US$ (% revenue) million/year) 2005 21,402 30 63.5 0.15 0.042 3,292.6 548 2007 14,901 36 88 0.15 0.048 2,214.4 292 2008 16,712 22 88 0.15 0.051 2,025.7 220 2009 16,652 20 88 0.15 0.047 1,997.7 247 Source: Eberhard and others 2009. Note: GWh = gigawatt-hour; kWh = kilowatt-hour. Figure 11. Evolution of hidden costs in Nigeria’s power sector 600 3.50 500 3.00 2.50 % of revenues 400 % of GDP 2.00 300 1.50 200 1.00 100 0.50 0 0.00 2005 2007 2008 2009 unaccounted losses underpricing collection inefficiencies % of GDP Source: Eberhard and others 2009. Note: It was not possible to obtain all the relevant parameters for 2006. 29 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE Figure 12. Nigeria’s power sector presents high hidden costs Hidden costs of power utilities in select countries Nigeria 2005 Nigeria 2009 Niger Cameroon Senegal Ghana Cote d'Ivoire Cape Verde Burkina Faso Benin South Africa 0 100 200 300 400 500 600 % of utility revenues unaccounted losses collection inefficiencies underpricing Source: Eberhard and others 2009. Figure 13. Comparison of electricity tariffs across Africa 30 US$ cents per kilowatt-hour 25 20 15 10 5 0 Source: Derived from Eberhard and others 2009. Water resources Achievements Nigeria has made some progress toward developing an institutional framework suitable for irrigation development. The country has adopted a water policy, together with an irrigation strategy and action plan. There are specialized agencies for basin-level management, and water-user associations have been empowered. Nevertheless, there is still no specialized entity dedicated to the development of irrigation infrastructure. 30 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE Challenges Even compared to its African peers, Nigeria’s water storage capacity is low. It stands at 339 m3 per capita, compared with 838 m3 per capita for Sub-Saharan Africa as a whole. Nigeria has just under 300,000 hectares equipped for irrigation today. This is less than 1 percent of the country’s cultivated area, although a further 2 percent of the cultivated area is subject to some degree of water management, falling short of irrigation. The existing irrigated area is thinly spread across the national territory, most of it in narrow strips flanking the nation’s rivers (recall figure 3d). Even in the areas where some irrigation is taking place, the level of intensity is low; only a fraction is being irrigated. Furthermore, of the limited area equipped for irrigation, only 75 percent is actually operating. The 1 percent of land that is irrigated produces 4.4 percent of the value of Nigeria’s agricultural produce. The rate of expansion of irrigated area, though historically slow, has been picking up in recent years. Over the period 1973 to 2003, irrigated area expanded slowly, by only 1.2 percent each year—about half the pace of Sub-Saharan Africa. Since 2003, however, the rate of expansion has increased to 3.1 percent annually, more than twice as high as in the rest of Sub-Saharan Africa. Nigeria has huge unexploited potential for economically attractive irrigation schemes. A simulation exercise exploring the economic viability of further expanding large- and small-scale irrigation schemes concluded that Nigeria has by far the best prospects for irrigation development of any country in Sub- Saharan Africa (table 10). If all land with a positive rate of return is considered, the potential is as high as 5.7 million hectares—which is almost as much as the total irrigated land in Sub-Saharan Africa today. About half of the potential lies in large-scale schemes. Nevertheless, the internal rate of return on the large-scale schemes, at 7 percent, is not even one-third the estimated 22 percent return on small-scale schemes. The viable area for irrigation is highly sensitive to the hurdle rate of return used. As the hurdle rate is increased beyond zero, the number of viable hectares shrinks dramatically to just over 2 million for hurdle rates in the 6–12 percent range. Moreover, the composition of viable schemes shifts markedly toward smaller-scale projects that offer higher rates of return overall. The overall internal rate of return for surviving projects rises to around 30 percent. If the hurdle rate is raised further to 24 percent, the number of viable hectares shrinks to 0.8 million, almost all of them for small-scale schemes. More generally, it has been found that the viability of irrigation schemes depends on crops—mainly cash crops and horticulture—that are capable of generating in excess of $2,000 per hectare. 31 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE Figure 14. Irrigation schemes are viable across much of the country, with pockets of higher returns Areas viable for irrigation Source: You and others 2009. Table 10. Sensitivity of irrigation potential to thresholds for economic return Potential (‘000s hectares) Investment needs (US$ million) Average IRR (%) Large Small Total Large Small Total Large Small Total scale scale scale scale scale scale IRR >0% 3,169 2,505 5,674 6,185 12,942 19,127 7.1 22.0 17.2 IRR >6% 370 1,945 2,315 723 10,048 10,771 23.8 29.0 28.6 IRR >12% 609 1,538 2,147 1,188 7,948 9,136 18.4 36.0 33.7 IRR >24% 34 788 822 66 4,070 4,137 32.5 54.0 53.7 Source: You and others 2009. Notes: Simulations based on assumptions that large-scale irrigation can be developed at a cost of $3,000 per hectare and small-scale irrigation can be developed at a cost of $2,000 per hectare. Should these costs be significantly exceeded, the number of viable hectares falls sharply. IRR = internal rate of return. Results are also highly sensitive to the costs of irrigation development. The results presented are based on unit-cost assumptions of $3,000 per hectare for large-scale schemes and $2,000 per hectare for small-scale schemes. These represent best-practice cost benchmarks, though actual development costs experienced in West Africa might be substantially higher, which would dramatically reduce the estimated 32 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE number of viable hectares. Based on these cost assumptions, the required one-time investment to develop all viable schemes (based on a hurdle rate of 12 percent) would be on the order of $9.1 billion. Information and communications technologies Achievements In common with the rest of Africa, Nigeria has made good progress in expanding GSM signal coverage. The percentage of Nigeria’s population living within range of a GSM signal has expanded rapidly, reaching some 60 percent in 2006 and nearly 70 percent in 2009. Nigeria has attracted over half the $28 billion in private capital that has gone into the development of new mobile networks across Africa.2 Nigeria stands out among African countries for its creation of a competitive fixed-line sector. The key reason for this is market liberalization: there were 30 active, fixed-wireless operators as of December 2009 (NCC 2010). Most are providing service using fixed-wireless technology (with four fixed-wireless operators competing head on with GSM operators by providing full mobility functionality). As a result, only a minority of fixed-line subscribers are associated with the stagnating national incumbent Nigerian Telecommunications Limited (NITEL), which, as of 2009, remained unprivatized (IHS Global Insight 2008). Intense competition in the mobile and fixed-line segments has driven prices down. Nevertheless, the 2009 prices of a monthly fixed-line subscription ($9) and prepaid mobile subscription ($11) were only average compared with other Sub-Saharan African countries. As of 2010 significant tariff reductions were following the lower interconnection rates introduced by the regulator. This, combined with the depreciation of the naira, should make ICT services more affordable. Nigeria has also made great progress in the development of a national fiber-optic network by harnessing private sector investment. Many African countries have pursued publicly sponsored national fiber-optic backbone networks, some of them quite expensive and of relatively low quality. Nigeria, on the other hand, has taken full advantage of the scale of its market. By liberalizing the market for fiber- optic infrastructure, the country has seen substantial private sector investment in this area, leading to the development of a solid backbone network interconnecting the major cities (figure 15). Multiple parallel cables have been laid on the highest-traffic routes, which has resulted in intense competition and a decrease in costs. Evidently the private sector will not of its own accord extend cables into smaller towns and rural areas, where a business case does not exist. But by first allowing the private sector to develop the major components of the backbone, the government can limit the use of public funds to areas where no other solution is possible, thereby saving significant fiscal resources. 2 Over the past decade, some $16 billion has been invested in projects related to mobile services in Nigeria. See Pyramid Research (2010). 33 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE Figure 15. Private sector investment in Nigeria’s national fiber-optic backbone Challenges Nigeria still faces a substantial market-efficiency gap in the mobile market. While Nigeria’s existing level of GSM signal coverage is impressive—practically all urban areas are fully covered and around half of the rural population is within reach of a signal—simulations suggest that the GSM signal might profitably be extended to 100 percent of the national population (figure 12). It is puzzling that coverage is not greater, given that with nine mobile operators, Nigeria arguably has the most competitive mobile market on the continent. But the price of mobile licenses, coupled with the challenge of extending infrastructure in a large country, pushes up operators’ costs. Another bottleneck is a lack of electricity in rural areas, which further inflates the costs of network rollout (Mayer 2010). Only around one-third of rural households had electricity in 2008, about the same fraction as rural households with a mobile telephone (NPC and ICF Macro 2009). The price of Internet access remains high, but can be expected to fall with the arrival of new submarine cables. Internet access is relatively expensive considering that Nigeria has access to the SAT-3 submarine cable. But NITEL has had a de facto monopoly over the international gateway. The launch of the Main One undersea fiber-optic cable in 2010, with landing stations in Nigeria and Ghana, was forecast to reduce wholesale prices by 50 percent (TradeInvestNigeria 2010). As of 2010, the imminent arrival of additional submarine cable projects along the West African coast has already placed downward pressure on costs. If costs effectively fall, Nigeria could emerge as a leading regional bandwidth supplier (Business Day 2010). Evidence from across Africa suggests that only when there is competitive access to submarine cable infrastructure are the full cost advantages felt by consumers (table 11). 34 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE Figure 16. Nigeria still has a substantial efficient-market gap for GSM coverage Congo, Dem. Rep. of Madagascar Zambia Congo, Rep. of Niger Mozambique Chad Botswana Namibia Lesotho Tanzania Ethiopia Cameroon Cape Verde Burkina Faso Malawi Sudan Kenya Senegal Côte d’Ivoire Benin Ghana Uganda Rwanda Nigeria South Africa 0% 10% 20% 30% 40% 50% 60% 70% 80% 90% 100% % of population coverage gap efficient market gap existing access Source: Mayer and others 2008. Note: Gray = the percentage of the population covered by voice infrastructure as of the third quarter of 2006. White = the efficient-market gap—the percentage of the population for whom voice telecommunications services are commercially viable, given efficient and competitive markets. Black = the coverage gap—the percentage of the population for whom services are not viable without a subsidy. 35 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE Table 11. High international call charges driven both by technology and market power US$ Percent Call within Sub- Call to the Internet dial-up Internet cases Saharan Africa United States ADSL (%) Without submarine cable 67 1.34 0.86 68 283 With submarine cable 33 0.57 0.48 47 111 Monopoly on international gateway 16 0.70 0.72 37 120 Competitive international gateway 16 0.48 0.23 37 98 Source: Mayer and others 2008. ADSL = asymmetric digital subscriber line. Table 12. Benchmarking ICT indicators 2006 2008 2009 Unit Nigeria Nigeria Lower-middle- Sub-Saharan Nigeria income group Africa GSM coverage % population 61.8 61.8 77 56 68.7 International bandwidth Bits/second/person 1.1 5 153 34 — Internet Users/100 people 10.5 4.5 13.9 6.5 17.3 Landline Subscribers/100 people 1.2 0.9 34.8 1.5 0.9 Mobile phone Subscribers/100 people 23.1 42.6 30.6 33.3 48.1 2006 2008 2009 Lower-middle- US$ Nigeria Nigeria income group Sub-Saharan Africa Nigeria Price of monthly mobile basket 12.2 14.3 8.4 11.8 11.5 Price of monthly fixed-line basket 7.8 8.3 4.8 11.6 9.1 Price of monthly fixed broadband — 54.1 31.4 100.1 43.1 Price of a call to the United States (peak n.a. 0.88 0.27 minute) 0.42 0.31 Price of inter-Africa calls (peak minute) 0.70 0.31 n.a. 1.02 0.27 Sources: World Bank, ICT At-a-Glance, and AICD database. Note: GSM = global system for mobile communications. — = Not available; n.a. = not applicable; * = mean. Financing Nigeria’s infrastructure To meet its most pressing infrastructure needs and to catch up with developing countries in other parts of the world, Nigeria needs to expand its infrastructure assets in key areas (table 13). The targets outlined in table 13 are purely illustrative, but they represent a level of aspiration that is not unreasonable. Developed in a standardized way across African countries, the standardized targets allow for cross- country comparisons of their affordability. The targets can be modified or delayed as needed to achieve financial balance. 36 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE Table 13. Potential investment targets for infrastructure in Nigeria Economic target Social target ICT Fiber-optic links to neighboring capitals Universal access to GSM signal and submarine cables. and public broadband facilities. Irrigation Develop 608,755 hectares of large-scale irrigation and 1,538,121 hectares of small-scale irrigation. n.a. Power 10,828 MW new generation and Electricity coverage of 82% 366 MW interconnectors. (100% urban and 49% rural). Transport Regional connectivity by good-quality 2-lane paved road. Rural network giving access to 47% agricultural production. National connectivity by good-quality 1-lane paved road. Urban population within 500 meters paved road. WSS Sustain MDG target for water and sanitation, n.a. and clear sector rehabilitation backlog. Sources: Mayer and others 2008; Rosnes and Vennemo 2009; Carruthers and others 2009; You and others 2009. Note: GSM = global system for mobile communications; ICT = information and communications technology; MW = megawatts; WSS = water supply and sanitation; MDG = Millennium Development Goals. n.a. = Not applicable. Meeting these illustrative infrastructure targets for Nigeria would cost $14.2 billion annually through 2015, most of it for federal infrastructure (table 13). Since the AICD project was only able to collect information on federal infrastructure spending, the analysis in this section will focus exclusively on federal infrastructure financing. The total spending requirement, therefore, needs to be estimated across jurisdictions. For this purpose, it is assumed that the federal government takes responsibility for ICT, large-scale irrigation, power, primary roads, railways, ports, and airports. The bulk of the identified spending requirements—some $10.5 billion annually in all—relates to these federal infrastructure assets. The remaining areas of infrastructure, including water and sanitation, secondary and tertiary road networks, and small-scale irrigation, are assumed to be state- or municipal-level responsibilities. The total price tag for infrastructure in these spheres amounts to $3.7 billion a year, and will not be further considered in this section. Federal infrastructure spending needs are strongly skewed toward capital investment, and heavily dominated by the power sector. Capital expenditure accounts for 71 percent of total federal spending requirements. The highest price tag is associated with the power sector and is on the order of $7.6 billion annually, which is about as much as the other four sectors put together. Spending in the power sector would go toward providing 10,828 MW of new generation capacity to meet demands over the next decade, as well as toward boosting electrification to 82 percent (table 14). 37 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE Table 14. Indicative infrastructure spending needs in Nigeria for 2006 to 2015 US$ million per year Federal needs National needs Sector Capital expenditure O&M Total Total ICT 1,960 103 2,063 2,063 Irrigation 145 0 145 939 Power 4,903 2,690 7,593 7,593 Transport 404 256 661 1,222 WSS 0 0 0 2,340 Total 7,412 3,050 10,462 14,158 Sources: Mayer and other 2008; Rosnes and Vennemo 2009; Carruthers and others 2009; and You and others 2009. Derived from models that are available online at http://www.infrastructureafrica.org/aicd/tools/models. Note: O&M = operations and maintenance; ICT = information and communications technology; WSS = water supply and sanitation. Nigeria’s infrastructure spending needs are not unmanageable when viewed against the size of the national economy. The country’s overall spending needs would absorb 12 percent of GDP, while federal spending needs alone amount to 9 percent of GDP. This GDP share is similar to what is found for other resource-rich African economies, but substantially lower than the burden for low-income states that lack natural resource endowments (figure 12). Overall investment needs for infrastructure would amount to about 9 percent of GDP. This is well below the 15 percent that China invested in its infrastructure during the early to mid-2000s. Figure 17. Nigeria’s infrastructure spending needs are substantial relative to GDP Estimated infrastructure spending needed to meet targets, as percentage of GDP Sub-Saharan Africa Low-income countries, nonfragile Low-income countries, fragile ECOWAS Resource-rich Middle-income countries Senegal Niger Mali Ghana Benin Côte d'Ivoire Nigeria Burkina Faso Cape Verde 0 10 20 30 40 % of GDP capex operations and maintenance Source: Foster and Briceño-Garmendia 2009. 38 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE Note: ECOWAS = Economic Community of West African States; SSA = Sub-Saharan Africa; GDP = gross domestic product; O&M = operations and maintenance. At present, Nigeria is spending only $5.9 billion on federal infrastructure needs (table 15). As much as 90 percent of the total is allocated to capital expenditure and 10 percent to operating expenditure. Operating expenditure is entirely covered from budgetary resources and user charges, and is strikingly low in the case of the transport and irrigation sectors. By far the largest source of investment finance is the private sector, which has been contributing $2.5 billion a year. Although heavily skewed toward ICT, the private sector has also made significant contributions to the funding of power and transport infrastructure. Public investment is in second place, at $1.7 billion per annum. Non-OECD finance comes third, at $0.9 billion a year, mainly in the power and transport sectors. Official development assistance (ODA) of Nigeria’s federal infrastructure is negligible. Federal infrastructure spending absorbs about 5 percent of Nigeria’s GDP. This level of effort is relatively small compared to the Sub-Saharan average of around 8 percent of GDP (figure 13). Nevertheless, since it excludes subnational spending, it is very much a lower bound. The sources of infrastructure investment finance in Nigeria differ somewhat from the peer group (figure 14). Particularly noticeable is the limited role of ODA in the transport sector, as well as the absence of public investment in ICT. Table 15. Financial flows to Nigeria’s infrastructure, average 2001 to 2006 US$ millions per year Capital expenditure O&M Non-OECD Total Total (public sector) Public sector ODA financiers PPI CAPEX spending ICT 9 15 2 56 1,867 1,940 1,949 Irrigation 0 160 0 0 0 160 160 Power 685 716 35 309 209 1,269 1,954 Transport 112 780 26 537 422 1,765 1,877 Total 806 1,671 63 902 2,498 5,134 5,940 Source: Derived from Foster and Briceño-Garmendia (2009). Note: O&M = operations and maintenance; ODA = official development assistance; PPI = private participation in infrastructure; CAPEX = capital expenditure; OECD = Organisation for Economic Co-operation and Development. 39 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE Figure 18. Nigeria’s infrastructure spending is not high for the region Sub-Saharan Africa Low-income countries, fragile Low-income countries, nonfragile ECOWAS Resource-rich Middle-income countries Senegal Niger Mali Ghana Benin Côte d'Ivoire Nigeria Burkina Faso Cape Verde 0 5 10 15 20 25 % of GDP capex operations and maintenance Source: Foster and Briceño-Garmendia 2009. Note: GDP = gross domestic product; CAPEX = capital expenditure; ECOWAS = Economic Community of West African States. Figure 19. Nigeria’s pattern of capital investment in infrastructure differs from that of comparator countries Investment in infrastructure sectors as percentage of GDP, by source 2.0 Nigeria Resource-rich 1.5 % of GDP 1.0 0.5 0.0 public ODA non-OECD private Source: Derived from Briceño-Garmendia, Smits, and Foster (2009). Note: Private investment includes self-financing by households. OECD = Organisation for Economic Co-operation and Development; ICT = information and communications technology; WSS = water supply and sanitation; ODA = official development assistance (from OECD countries). 40 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE How much more can be done within the existing resource envelope? About $2.5 billion of additional resources could be recovered each year by improving efficiency (table 16). Due to various kinds of inefficiencies, resources currently in the system are remaining uncaptured for frontline infrastructure provision. The cost of this waste amounts to $2.5 billion a year, almost all of it associated with the power sector. Within the power sector, the largest source of inefficiency lies in the underrecovery of costs, followed by distribution losses and undercollection. Across the board, there also appears to be a systematic problem of low capital budget execution that each year prevents some $0.5 billion of resources allocated to infrastructure from being spent. This problem is equally significant in the power and transport sectors, and also substantially affects the irrigation sector. Table 16. Potential gains from greater operational efficiency ICT Irrigation Power Transport Total Underrecovery of costs — n.a. 1,677 n.a. 1,677 Overstaffing n.a. — n.a. — 0 Distribution losses — — 226 — 226 Undercollection — n.a. 94 n.a. 94 Low budget execution 3 55 173 224 455 Total 3 55 2,171 224 2,453 Source: Derived from Foster and Briceño-Garmendia (2009). Note: ICT = information and communications technology. — = Not available; n.a. = not applicable. As noted above, undercharging for power is the largest source of inefficiency; resources worth $1.7 billion fail to be captured each year, a hemorrhage equivalent to 1 percent of GDP. Nigeria’s average effective tariff, as of 2009, was just under $0.05 per kWh, barely one-third of the total historic cost of producing power in the country, which was estimated to be around $0.15 per kWh. As a result, the power utility was barely covering its operating costs, leaving most of the capital investment unfunded. The associated financial burden was a staggering 1 percent of GDP (figure 15). Figure 20. Underpricing of power and water in Nigeria is relatively burdensome Financial burden of underpricing in 2006, as percentage of GDP 1.2 1.0 0.8 % of GDP 0.6 0.4 0.2 0.0 Power Nigeria resource-rich Source: Derived from Briceño-Garmendia, Smits, and Foster (2009). 41 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE Because of the inequitable access to power in Nigeria, subsidized tariffs are highly regressive. About three-quarters of those with electricity connections belong to the top 40 percent of the expenditure distribution; connections are extremely rare among poor households (figure 16). This highly inequitable distribution of connections virtually guarantees that any price subsidy for these services will be extremely regressive. The affordability of cost-recovery infrastructure tariffs can be assessed by looking at the distribution of household budgets in Nigeria. A standard infrastructure affordability threshold of 5 percent of the budget is used. Relative to other low-income countries in Africa, the purchasing power of Nigeria’s households is somewhat higher, making any particular level of the monthly utility bill affordable to a higher share of households (figure 17). Monthly bills of up to $4 are affordable to the vast majority of households, while those over $12 can be afforded by only a few. Figure 21. Access to power in Nigeria is highly inequitable 100 80 % of population 60 40 20 0 Q1 Q2 Q3 Q4 Q5 Power Source: Banerjee and others 2009. Note: Q1 = first budget quintile, Q2 = second budget quintile, and so on. Cost-recovery tariffs are affordable for most Nigerian households, and in particular those that have access to power today. The monthly bill that would result from cost-recovery pricing by the utilities can be estimated using the cost-recovery benchmark tariff and applying it to a subsistence level of household consumption. A cost-recovery tariff of $0.15/kWh for power and a subsistence consumption of 50 kWh per month—which is enough to power two 100-watt light bulbs for eight hours a day—amounts to a monthly power bill of $7.50, which would be affordable for two-thirds of Nigeria’s population (figure 17). Given that as of today only 50 percent of households have access to power, and that these tend to be from the upper end of the income distribution, there does not seem to be any serious affordability problem among existing customers. Indeed, electrification rates would have to increase significantly across the lower-income groups before affordability became a serious issue. This is still some way ahead. 42 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE Figure 22. Affordability of utility bills percent of the monthly household utility bill would be less than 5 100 % of urban households whose 80 60 40 budget 20 0 2 4 6 8 10 12 14 16 Monthly utility bill (US$) Nigeria low-income countries Average cost of water is $0.40/month Average cost of power is $2.50/month Water cost-recovery tariff is $0.72/m3 Power cost-recovery tariff is $0.10/kwh Source: Banerjee and others 2009. The operational inefficiencies of the power sector are costing Nigeria $0.3 billion a year, or almost 0.2 percent of GDP (figure 18). About two-thirds of these hidden costs come from distribution losses and the remainder from undercollection of revenues. Indeed, despite recent improvements, Nigeria’s power sector presents distribution losses of 20 percent (twice that of best-practice levels) and collects only 88 percent of its revenue (compared to best-practice levels of 100 percent). As a result, Nigeria’s power utilities generate hidden costs for the economy equivalent to 0.2 percent of GDP. These findings are not atypical of other resource-rich countries in Africa. Figure 23. The burden of inefficiency in Nigeria’s power sector 0.4 0.3 % of GDP 0.2 0.1 0 Nigeria Resource-rich collection inefficiencies unaccounted lossses Source: Derived from Briceño-Garmendia, Smits, and Foster (2009). Annual funding gap Nigeria’s funding gap for federal infrastructure alone amounts to $3.6 billion per year, or about 3 percent of GDP. Almost the entire funding gap relates to the power sector (table 17). There is a small 43 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE shortfall for the ICT sector, while transport shows a surplus of capital spending even when some is reallocated within the sector toward maintenance. Table 17. Funding gaps by sector US$ millions ICT Irrigation Power Transport Total Spending needs (2,063) (145) (7,593) (661) (10,462) Existing spending 1,949 145 1,954 516 4,564 Reallocation potential within sectors 0 0 0 145 145 Efficiency gains 3 55 2,171 224 2,453 Funding gap (112) (3,468) (3,580) Source: Derived from Foster and Briceño-Garmendia (2009). Note: Potential overspending across sectors is not included in the calculation of the funding gap, because it cannot be assumed that it would be applied toward other infrastructure sectors. ICT = information and communications technology. — = Not available. What else can be done? Raising additional public funds for infrastructure should be relatively straightforward for Nigeria, given its sizeable resource rents. With its abundant petroleum revenues Nigeria is better placed than many of its African neighbors to increase the share of fiscal resources going to infrastructure. Nevertheless, evidence suggests that in the recent past, resource-rich countries—such as Nigeria—have not tended to allocate incremental resource royalties toward infrastructure. Instead, huge debt repayments more than fully absorbed the fiscal windfalls in these countries. As a result, budgetary spending actually contracted by 3.7 percent of GDP even during a period of high oil prices in the early 2000s, with infrastructure investment bearing much of that and falling by almost 1.5 percent of GDP. Another potential source for infrastructure finance, in an economy as large and solvent as Nigeria’s, are the domestic capital markets. Yet the country’s domestic capital markets function far below their potential. The outstanding stock of bank loans, government and corporate bonds, and equity issues channeled toward infrastructure is still only a fraction of what can be found in South Africa. The total outstanding value of the stock stood at no more than $2.5 billion in 2006 (table 18). Table 18. Local capital market finance for infrastructure in Africa Outstanding stock, US$ millions Bank loans Government Corporate Equity Total bonds bonds issues Nigeria 2,444 47 0 106 2,596 South Africa 6,275 763 6,841 48,148 62,028 Other Sub-Saharan Africa 2,564 93 548 7,691 10,896 Total 11,283 903 7,389 55,945 75,520 Source: Derived from Foster and Briceño-Garmendia (2009). Note: Potential overspending across sectors is not included in the calculation of the funding gap because it cannot be assumed that it would be applied toward other infrastructure sectors. — = Not available. * Traced to needs. ** Assuming complete fungibility across sectors. 44 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE Nigeria has proved to be an attractive destination for non-OECD financiers such as China, and could potentially do more to leverage interest. China’s commitment to financing Nigerian infrastructure has been apparent in recent years. But a number of major projects identified for Chinese funding have been dropped. This is a missed opportunity and points to the importance of lining up Chinese projects with national development priorities. Finally, if all else fails, it may be necessary to extend the time horizon for meeting the infrastructure targets beyond the illustrative 10-year period considered here. Simulations suggest that even if Nigeria is unable to raise additional finance, but if inefficiencies can be addressed, the identified infrastructure targets could be achieved within a 16-year horizon. But unless inefficiencies are eliminated, the existing resource envelope will not suffice to meet infrastructure targets in the medium term. 45 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE References and bibliography This country report draws upon a wide range of papers, databases, models, and maps that were created as part of the Africa Infrastructure Country Diagnostic. All of these can be downloaded from the project website: www.infrastructureafrica.org. For papers go to the document page (http://www.infrastructureafrica.org/aicd/documents), for databases to the data page (http://www.infrastructureafrica.org/aicd/tools/data), for models go to the models page (http://www.infrastructureafrica.org/aicd/tools/models), and for maps to the map page (http://www.infrastructureafrica.org/aicd/tools/maps ). The references for the papers that were used to compile this country report are provided below. General Foster, Vivien, and Cecilia Briceño-Garmendia, eds. 2009. Africa’s Infrastructure: A Time for Transformation. Paris and Washington, DC: Agence Française de Développement and World Bank. Growth Calderón, César. 2009. ―Infrastructure and Growth in Africa.‖ Policy Research Working Paper 4914, World Bank, Washington, DC. Escribano, Alvaro, J. Luis Guasch, and Jorge Pena. 2010. ―Assessing the Impact of Infrastructure Quality on Firm Productivity in Africa.‖ Policy Research Working Paper 5191, World Bank, Washington, DC. Estache, A., and M. Vagliasindi. 2007. ―Infrastructure for Accelerated Growth for Ghana: Needs and Challenges.‖ Background Paper, Country Economic Memorandum, World Bank, Washington, DC. Lall, S., J. Sandefur, and H. G. Wang. 2008. ―Can Industrial Development Bridge Ghana’s Spatial Divide?‖ Unpublished paper, World Bank, Washington, DC. Yepes, Tito, Justin Pierce, and Vivien Foster. 2009. ―Making Sense of Africa’s Infrastructure Endowment: A Benchmarking Approach.‖ Policy Research Working Paper 4912, World Bank, Washington, DC. Financing Briceño-Garmendia, Cecilia, Karlis Smits, and Vivien Foster. 2009. ―Financing Public Infrastructure in Sub-Saharan Africa: Patterns and Emerging Issues.‖ AICD Background Paper 15, Africa Region, World Bank, Washington, DC. 46 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE Information and communications technologies Ampah, Mavis, Daniel Camos, Cecilia Briceño-Garmendia, Michael Minges, Maria Shkaratan, and Mark Williams. 2009. ―Information and Communication technology in Sub-Saharan Africa: A Sector Review.‖ AICD Background Paper 10, Africa Region, World Bank, Washington, DC. Business Day. 2010. ―Nigeria May Become Leading Supplier of Bandwidth in Sub-Saharan Africa.‖ July 27. http://www.businessdayonline.com/index.php?option=com_content&view=article&id=13108:nig eria-may-become-leading-supplier-of-bandwidth-in-sub-saharan-africa&catid=1:latest- news&Itemid=18. IHS Global Insight. 2008. ―Nigerian Government Cancels Sale of NITEL, Seeks New Investor.‖ February 19. http://www.ihsglobalinsight.com/SDA/SDADetail11562.htm Mayer, R. 2010. ―Benefits of Reducing Power Operating Expenses in Nigeria’s Mobile Telecommunications Sector.‖ Unpublished paper. Mayer, Rebecca, Ken Figueredo, Mike Jensen, Tim Kelly, Richard Green, and Alvaro Federico Barra. 2008. ―Connecting the Continent: Costing the Needs for Spending on ICT Infrastructure in Africa.‖ AICD Background Paper 3, Africa Region, World Bank, Washington, DC. NCC (Nigerian Communications Commission). 2010. Quarterly Summary of Telephone Subscribers in Nigeria. Industry Statistics. http://www.ncc.gov.ng. NPC (National Population Commission) [Nigeria] and ICF Macro. 2009. Nigeria Demographic and Health Survey 2008. Pyramid Research. 2010. The Impact of Mobile Services in Nigeria: How Mobile Technologies Are Transforming Economic and Social Activities. http://www.ncc.gov.ng/industrystatistics/studies/Pyramid+Impact_Mobile_Services_Nigeria.pdf. TradeInvestNigeria. 2010. ―Main One Cable Goes Live.‖ July 2. http://www.tradeinvestnigeria.com/news/611667.htm. Irrigation Svendsen, Mark, Mandy Ewing, and Siwa Msangi. 2008. ―Watermarks: Indicators of Irrigation Sector Performance in Africa.‖ AICD Background Paper 4, Africa Region, World Bank, Washington, DC. You, L., C. Ringler, G. Nelson, U. Wood-Sichra, R. Robertson, S. Wood, G. Zhe, T. Zhu, and Y. Sun. 2009. ―Torrents and Trickles: Irrigation Spending Needs in Africa.‖ AICD Background Paper 9, Africa Region, World Bank, Washington, DC. 47 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE Power Banerjee, Sudeshna, Quentin Wodon, Amadou Diallo, Taras Pushak, Helal Uddin, Clarence Tsimpo, and Vivien Foster. 2009. ―Access, Affordability, and Alternatives: Modern Infrastructure Services in Africa.‖ AICD Background Paper 2, Africa Region, World Bank, Washington, DC. Eberhard, Antonne, Vivien Foster, Cecilia Briceño-Garmendia, Fatimata Ouedraogo, Daniel Camos, and Maria Shkaratan. 2009. ―Underpowered: The State of the Power Sector in Sub-Saharan Africa.‖ AICD Background Paper 6, Africa Region, World Bank, Washington, DC. Foster, Vivien, and Jevgenijs Steinbuks. 2009. ―Paying the Price for Unreliable Power Supplies: In-House Generation of Electricity by Firms in Africa.‖ Policy Research Working Paper 4913, World Bank, Washington, DC. Keener, S., and S. G. Banerjee. 2005. ―Ghana: Poverty and Social Impact Analysis of Electricity Tariffs.‖ ESMAP Technical Paper 088, World Bank, Washington, DC. Presidency. 2010. Road Map for Power Sector Reform: A Customer-Driven Sector Wide Plan to Achieve Stable Power Supply. Report, Federal Government of Nigeria. Abuja. Rosnes, Orvika, and Haakon Vennemo. 2009. ―Powering Up: Costing Power Infrastructure Spending Needs in Sub-Saharan Africa.‖ AICD Background Paper 5, Africa Region, World Bank, Washington, DC. Transport Bofinger, Heinrich C. 2009. ―An Unsteady Course: Growth and Challenges in Africa’s Air Transport Industry.‖ AICD Background Paper 16, Africa Region, World Bank, Washington, DC. Bullock, Richard. 2009. ―Off Track: Sub-Saharan African Railways.‖ AICD Background Paper 17, Africa Region, World Bank, Washington, DC. Carruthers, Robin, Ranga Rajan Krishnamani, and Siobhan Murray. 2009. ―Improving Connectivity: Investing in Transport Infrastructure in Sub-Saharan Africa.‖ AICD Background Paper 7, Africa Region, World Bank, Washington, DC. Gwilliam, Ken, Vivien Foster, Rodrigo Archondo-Callao, Cecilia Briceño-Garmendia, Alberto Nogales, and Kavita Sethi. 2009. ―The Burden of Maintenance: Roads in Sub-Saharan Africa.‖ AICD Background Paper 14, Africa Region, World Bank, Washington, DC. Kumar, Ajay, and Fanny Barrett. 2008. ―Stuck in Traffic: Urban Transport in Africa.‖ AICD Background Paper 1, Africa Region, World Bank, Washington, DC. Ocean Shipping Consultants, Inc. 2009. ―Beyond the Bottlenecks: Ports in Africa.‖ AICD Background Paper 8, Africa Region, World Bank, Washington, DC. 48 NIGERIA’S INFRASTRUCTURE: A CONTINENTAL PERSPECTIVE Water supply and sanitation Banerjee, Sudeshna, Vivien Foster, Yvonne Ying, Heather Skilling, and Quentin Wodon. 2008a. ―Cost Recovery, Equity, and Efficiency in Water Tariffs: Evidence from African Utilities.‖ AICD Working Paper 7, World Bank, Washington, DC. Banerjee, Sudeshna, Heather Skilling, Vivien Foster, Cecilia Briceño-Garmendia, Elvira Morella, and Tarik Chfadi. 2008b. ―Ebbing Water, Surging Deficits: Urban Water Supply in Sub-Saharan Africa.‖ AICD Background Paper 12, Africa Region, World Bank, Washington, DC. Banerjee, Sudeshna, Quentin Wodon, Amadou Diallo, Taras Pushak, Helal Uddin, Clarence Tsimpo, and Vivien Foster. 2009. ―Access, Affordability, and Alternatives: Modern Infrastructure Services in Africa.‖ AICD Background Paper 2, Africa Region, World Bank, Washington, DC. Gulyani, Sumila, Debabrata Talukdar, and Darby Jack. 2009. ―Poverty, Living Conditions, and Infrastructure Access: A Comparison of Slums in Dakar, Johannesburg, and Nairobi.‖ AICD Working Paper 10, World Bank, Washington, DC. Keener, Sarah, Manuel Luengo, and Sudeshna Banerjee. 2009. ―Provision of Water to the Poor in Africa: Experience with Water Standposts and the Informal Water Sector.‖ AICD Working Paper 13, World Bank, Washington, DC. Morella, Elvira, Vivien Foster, and Sudeshna Ghosh Banerjee. 2008. ―Climbing the Ladder: The State of Sanitation in Sub-Saharan Africa.‖ AICD Background Paper 13, Africa Region, World Bank, Washington, DC. WHO (World Health Organization). 2010. Joint Monitoring Programme. Geneva. 49 About AICD and its country reports This study is a product of the Africa Infrastructure Country Diagnostic (AICD), a project designed to expand the world’s knowledge of physical infrastructure in Africa. The AICD provides a baseline against which future improvements in infrastructure services can be measured, making it possible to monitor the results achieved from donor support. It also offers a solid empirical foundation for prioritizing investments and designing policy reforms in Africa’s infrastructure sectors. The AICD is based on an unprecedented effort to collect detailed economic and technical data on African infrastructure. The project has produced a series of original reports on public expenditure, spending needs, and sector performance in each of the main infrastructure sectors, including energy, information and communications technologies, irrigation, transport, and water and sanitation. Africa’s Infrastructure—A Time for Transformation, published by the World Bank and the Agence Française de Développement in November 2009, synthesized the most significant findings of those reports. The focus of the AICD country reports is on benchmarking sector performance and quantifying the main financing and efficiency gaps at the country level. These reports are particularly relevant to national policy makers and development partners working on specific countries. The AICD was commissioned by the Infrastructure Consortium for Africa following the 2005 G8 (Group of Eight) summit at Gleneagles, Scotland, which flagged the importance of scaling up donor finance for infrastructure in support of Africa’s development. The first phase of the AICD focused on 24 countries that together account for 85 percent of the gross domestic product, population, and infrastructure aid flows of Sub-Saharan Africa. The countries are: Benin, Burkina Faso, Cape Verde, Cameroon, Chad, Côte d’Ivoire, the Democratic Republic of Congo, Ethiopia, Ghana, Kenya, Lesotho, Madagascar, Malawi, Mozambique, Namibia, Niger, Nigeria, Rwanda, Senegal, South Africa, Sudan, Tanzania, Uganda, and Zambia. Under a second phase of the project, coverage was expanded to as many of the remaining African countries as possible. Consistent with the genesis of the project, the main focus is on the 48 countries south of the Sahara that face the most severe infrastructure challenges. Some components of the study also cover North African countries so as to provide a broader point of reference. Unless otherwise stated, therefore, the term Africa is used throughout this report as a shorthand for Sub-Saharan Africa. The World Bank has implemented the AICD with the guidance of a steering committee that represents the African Union, the New Partnership for Africa’s Development (NEPAD), Africa’s regional economic communities, the African Development Bank (AfDB), the Development Bank of Southern Africa (DBSA), and major infrastructure donors. Financing for the AICD is provided by a multidonor trust fund to which the main contributors are the United Kingdom’s Department for International Development (DFID), the Public Private Infrastructure Advisory Facility (PPIAF), Agence Française de Développement (AFD), the European Commission, and Germany’s Entwicklungsbank (KfW). A group of distinguished peer reviewers from policy-making and academic circles in Africa and beyond reviewed all of the major outputs of the study to ensure the technical quality of the work. The Sub-Saharan Africa Transport Policy Program and the Water and Sanitation Program provided technical support on data collection and analysis pertaining to their respective sectors. The data underlying AICD’s reports, as well as the reports themselves, are available to the public through an interactive Web site, www.infrastructureafrica.org, that allows users to download customized data reports and perform various simulations. Many AICD outputs will appear in the World Bank’s Policy Research Working Papers series. Inquiries concerning the availability of data sets should be directed to the volume editors at the World Bank in Washington, DC.