Renewable energy in Africa

Last updated
Global Horizontal Irradiation in Sub-Saharan Africa. Sub-Saharan-Africa GHI mid-size-map 156x192mm-300dpi v20170928.png
Global Horizontal Irradiation in Sub-Saharan Africa.

The developing nations of Africa are popular locations for the application of renewable energy technology. Currently, many nations already have small-scale solar, wind, and geothermal devices in operation providing energy to urban and rural populations. These types of energy production are especially useful in remote locations because of the excessive cost of transporting electricity from large-scale power plants. The applications of renewable energy technology has the potential to alleviate many of the problems that face Africans every day, especially if done in a sustainable manner that prioritizes human rights.


Access to energy is essential for the reduction of poverty and promotion of economic growth. Communication technologies, education, industrialization, agricultural improvement and expansion of municipal water systems all require abundant, reliable, and cost-effective energy access. [2]

Avoiding fossil fuels

By investing in the long-term energy solutions that alternative energy sources afford, most African nations would benefit significantly in the longer term by avoiding the pending economic problems developed countries are currently facing.

Although in many ways fossil fuels provide a simple, easy to use energy source that powered the industrialization of most modern nations, the issues associated with the widespread use of fossil fuels are now numerous, consisting of some of the world's most difficult and large-scale global political, economic, health and environmental problems. [3] The looming energy crisis results from consuming these fossil fuels at a rate which is unsustainable, with the global demand for fossil fuels expected to increase every year for the next several decades, compounding existing problems. [4]

While a great number of projects are currently underway to expand and connect the existing grid networks, [5] too many problems exist to make this a realistic option for the vast majority of people in Africa, especially those who live in rural locations. Distributed generation using renewable energy systems is the only practical solution to meet rural electrification needs. [6] [7] There is a move towards energy decentralization in African nations, with many looking towards variants of energy decentralization frameworks, such as District Energy Officers, for example as described in a recommendations paper for District Energy Officers for the country of Malawi. [8]

Renewable energy resources

Hydro-electric, wind and solar power all derive their energy from the Sun. The Sun emits more energy in one second (3.827 × 1026 J) than is available in all of the fossil fuels present on earth (3.9 × 1022 J), [9] and therefore has the potential to provide all of our current and future global energy requirements. Since the solar source for renewable energy is clean and free, African nations can protect their people, their environment, and their future economic development by using renewable energy sources [10] To this end they have a number of possible options. [11]

Solar resources

World map of global solar horizontal irradiation Global Map of Global Horizontal Radiation.png
World map of global solar horizontal irradiation

Africa is the sunniest continent on Earth, especially as there are many perpetually sunny areas like the huge Sahara Desert. [12]

It has much greater solar resources than any other continent. Desert regions stand up as the most sunshiny while rain forests are considerably cloudier but still get a good global solar irradiation because of the proximity with the equator.

The distribution of solar resources across Africa is fairly uniform, with more than 85% of the continent's landscape receiving at least 2,000 kWh/(m² year). A recent study indicates that a solar generating facility covering just 0.3% of the area comprising North Africa could supply all of the energy required by the European Union. [13] This is the same land area as the state of Maine.

Wave and wind resources

World map of wind power density. Global Map of Wind Power Density Potential.png
World map of wind power density.

Africa has a large coastline, where wind power and wave power resources are abundant and underutilized in the north and south. Geothermal power has potential to provide considerable amounts of energy in many eastern African nations. [15]

Wind is far less uniformly distributed than solar resources, with optimal locations positioned near special topographical funneling features close to coastal locations, mountain ranges, and other natural channels in the north and south. The availability of wind on the western coast of Africa is substantial, exceeding 3,750 kW·h, and will accommodate the future prospect for energy demands [16] [17] Central Africa has lower than average wind resources to work with. [18]

Geothermal resources

The Rift Valley near Eldoret, Kenya Africa6 006.jpg
The Rift Valley near Eldoret, Kenya

Geothermal power is mostly concentrated in eastern Africa, but there are many fragmented spots of high intensity geothermal potential spread across the continent. [19] There is enormous potential for geothermal energy in the East African Rift which is roughly 5,900 kilometers in length and spans several countries in East Africa including Eritrea, Ethiopia, Djibouti, Kenya, Uganda, and Zambia. [15]


The use of biomass fuels endangers biodiversity and risks further damaged or destruction to the landscape. 86% of Africa's biomass energy is used in the sub-Saharan region, excluding South Africa. [20] Even where other forms of energy are available, it is not harnessed and utilized efficiently, underscoring the need to promote energy efficiency where energy access is available. [21]

There is, however, an urgent need to address the current levels of respiratory illness from burning biomass in the home. Taking into respect the cost differential between the biomass and fossil fuels, it is far more cost-effective to improve the technology used to burn the biomass than to use fossil fuels. [22]

Horizontal integration potential

Solar and wind power are extremely scalable, as there are systems available from less than 1 watt to several megawatts. This makes it possible to initialize the electrification of a home or village with minimal initial capital. It also allows for dynamic and incremental scaling as load demands increases. The component configuration of a wind or solar installation also provides a level of functional redundancy, improving the reliability of the system. If a single panel in a multi-panel solar array is damaged, the rest of the system continues functioning unimpeded. In a similar way, the failure of a single wind tower in a multi-tower configuration does not cause a system-level failure.

Because solar and wind projects produce power where it is used, they provide a safe, reliable and cost-effective solution. Because transmission equipment is avoided, these systems are more secure, and less vulnerable to attack. [23] This can be an important feature in regions prone to conflict. Wind and solar power systems are simple to set up, easy to operate, easy to repair, and durable. Wind resources and solar resource are abundant enough to provide all of the electrical energy requirements of rural populations, and this can be done in remote and otherwise fragmented low-density areas that are impractical to address using conventional grid-based systems. [24]


Photo-voltaic panels, wind turbines deep cycle batteries, meters, sockets cables, and connectors are all expensive. Even when the relative difference in buying power, materials cost, opportunity cost, labor cost and overhead is factored in, renewable energy will remain expensive for people who are living on less than US$1 per day. Many rural electrification projects in the past use government subsidies to finance the implementation of rural development programs. It is difficult for rural electrification projects to be accomplished by for-profit companies; in economically impoverished areas these programs must be run at a loss for reasons of practicality. [25] There are several theorized ways in which specific African nations can rally the resources for such projects.

Potential funding sources

European countries that consume oil refined from African countries have the opportunity to subsidize the costs of individual level, village level, or community level alternative energy systems through emissions trading credits. It has been proposed that for every unit of African origin carbon consumed by the European market, a predetermined amount green credits or carbon credits would be yielded. [26] The European partners could then either supply parts, components, or systems directly, an equivalent amount of investment capital, or lend credits to finance the distribution of renewable energy services, knowledge or equipment. [27]

International relief targeted at poverty reduction could also be redirected towards subsidizing renewable energy projects. Because of the integral role that electrification plays in supporting economic and social development, funding of rural electrification can be seen as the core method for addressing poverty. Radios, televisions, telephones, computer networks, and computers all rely on an access to electricity. Because information services allow for the proliferation of education resources, funding the electric backbone to such systems has a derivative effect on their development. In this way, access to communications and education plays a major role in reducing poverty. Additionally, international efforts that supply equipment and services rather than money, are more resistant to resource misappropriation issue that pose problems in less stable governments. [28]

UNEP has developed a loan program to stimulate renewable energy market forces with attractive return rates, buffer initial deployment costs and entice consumers to consider and purchase renewable technology. After a successful solar loan program sponsored by UNEP that helped 100,000 people finance solar power systems in developing countries like India, [29] UNEP started similar schemes in other parts of the developing world like AfricaTunisia, Morocco, and Kenya projects are already functional and many projects in other African nations are in the pipeline. [30] In Africa, UNEP assistance to Ghana, Kenya, and Namibia has resulted in the adoption of draft National Climate Awareness Plans, publications in local languages, radio programs and seminars. [31] The Rural Energy Enterprise Development (REED) initiative is another flagship UNEP effort focused on enterprise development and seed financing for clean energy entrepreneurs in developing countries of West and Southern Africa. [32]

The Government of South Africa has set up the South African Renewables Initiative (SARi) [33] to develop a financing arrangement that would enable a critical mass of renewables to be developed in South Africa, through a combination of international loans and grants, as well as domestic funding. This has been a highly successful program now known as the REIPPP (Renewable Energy Independent Power Producer Program) with four rounds of allocations already completed. In Round 1, 19 projects were allocated, in Round 2, 28 projects were allocated, in Round 3, 17 projects were allocated and in Round 4, 26 projects were allocated. Over 6100MW has been allocated with a total of R194 billion (US$16 billion) being invested in this program. It is important to note that this investment figure represents full funding from private entities and banks – there are no government subsidies for this program.

Energy sector regulators as facilitators

The funding of renewable energy (RE) projects is dependent on the credibility of the institutions developing and implementing RE policy. This places a particular burden on the energy regulators in Africa, whose professional staff may be few in number and who have track records of only a decade or so. Rules (micro policies) made by regulators are subsidiary to overall government RE policy and depend on some delegation of authority from the state. Nevertheless, there are instances when the sector regulator can pro-active on behalf of customer and utility concerns—providing facts, reports, and public statements that build a case for care in the design of public policy towards RE. Clean and renewable energy is likely to be of concern to a number of organizations. Interaction between multiple authorities requires coordination to align policies, incentives, and administrative processes (including licensing and permitting). Of course, the making of policy by regulators is incidental to and inherent in their duty to decide specific cases or disputes. This micro policy-making role is derived from the fact that macro RE policy cannot reasonably be expected to anticipate all aspects of policy that will have to evolve for the regulatory process to be fully functional. This point is particularly important in the area of renewable energy, with its rapidly changing technologies and ever-changing public (and political) attitudes. Gaps will have to be filled and it is the regulators, with their functional responsibilities, technical expertise, and hands-on experience that are best positioned to accomplish that task in developing countries. Thus, for designing auctions for purchasing power, for establishing feed-in tariffs, or other instruments promoting RE, the energy sector regulator has a significant impact on the penetration of RE in Africa and other regions. [34]

Renewable energy use

Solar power

Global Horizontal Irradiation in Sub-Saharan Africa. Sub-Saharan-Africa GHI mid-size-map 156x192mm-300dpi v20170928.png
Global Horizontal Irradiation in Sub-Saharan Africa.

Several large-scale solar power facilities are under development in Africa including projects in South Africa and Algeria. [36] Although solar power technology has the potential to supply energy to large numbers of people, and has been used to generate power on a large scale in developed nations, its greatest potential in Africa may be to provide power on a smaller scale and to use this energy to help with day-to-day needs such as small-scale electrification, desalination, water pumping, and water purification.

The first utility-scale solar farm in Sub-Saharan Africa is the 8.5MW plant at Agahozo-Shalom Youth Village, in the Rwamagana District, Eastern Province of Rwanda. It leased 20 hectares (49 acres) of land from the village which is a charity to house and educate Rwandan genocide victims. The plant uses 28,360 photovoltaic panels and produces 6% of total electrical supply of the country. The project was built with U.S., Israeli, Dutch, Norwegian, Finnish and UK funding and expertise. [37]

There are several examples of small grid-linked solar power stations in Africa, including the photovoltaic 250 kW Kigali Solaire station in Rwanda. [38] Under the South Africa Renewable Energy Independent Power Producer Procurement Program, [39] several projects have been developed, including the 96MW(DC) Jasper Solar Energy Project, [40] the 75MW(DC) Lesedi PV project, [41] and the 75MW(DC) Letsatsi PV Project, [42] all developed by the American company SolarReserve and completed in 2014.

Power Up Gambia, a non-profit operating in The Gambia, uses solar power technology to provide power to Gambian health care facilities, providing a reliable source of electricity for lighting, diagnostic testing, treatments, and water pumping. [43] [44] Energy For Opportunity (EFO), a non-profit working in West Africa, uses solar power for Schools, Health Clinics and Community Charging Stations, as well as teaches Photovoltaic installation classes at local technical institutes. So far its work has been mainly in Sierra Leone. [45] In particular its solar powered Community Charging Stations have been recognized as an innovative model to provide electricity to rural communities in the region. [46] [47]

Some plans exist to build solar farms in the deserts of North Africa to supply power for Europe. The Desertec project, backed by several European energy companies and banks, planned to generate renewable electricity in the Sahara desert and distribute it through a high-voltage grid for export to Europe and local consumption in North-Africa. Ambitions seek to provide continental Europe with up to 15% of its electricity. The TuNur project would supply 2GW of solar generated electricity from Tunisia to the UK.

Solar water pumping

One of the most immediate and lethal problems facing many third world countries is the availability of clean drinking water. Solar powered technologies can help alleviate this problem with minimal cost using a combination of solar powered well pumping, a water tower or other holding tank, and a solar powered water purifier. These technologies require minimal maintenance, have low operational costs, and once set up, will help provide clean water for drinking and agriculture. With large enough reservoirs for the water that has been pumped and purified with solar powered technology, a community will be better able to withstand drought or famine. This reservoir water could be consumed by humans, livestock, or used to irrigate community gardens and fields, thus improving crop yields and community health. A solar powered water purification system can be used to clean many pathogens and germs from groundwater and runoff. A group of these devices, filtering the water from wells or runoff could help with poor sanitation and controlling the spread of waterborne illnesses.

Kenya may be a good candidate for testing out these systems because of its progressive and relatively well-funded department of agriculture, including the Kenya Agricultural Research Center, which provides funding and oversight to many projects investigating experimental methods and technologies.

Even though this solar technology may have a higher starting cost than that of conventional fossil fuel, the low maintenance and operation cost and the ability to operate without fuel makes the solar powered systems cheaper to keep running. A small rural community could use a system like this indefinitely, and it would provide clean drinking water at a negligible cost after the initial equipment purchase and setup. In a larger community, it could at least contribute to the water supply and reduce pressures of daily survival. This technology is capable of pumping hundreds of gallons of water per day, and is limited only by the amount of water available in the water table.

With a minimum of training in operation and maintenance, solar powered water pumping and purification systems have the potential to help rural Africans fulfill one of their most basic needs for survival. Further field test are in progress by organizations like KARI and the many corporations that manufacture the products needed, and these small-scale applications of solar technology are promising. Combined with sustainable agricultural practices and conservation of natural resources, solar power is a prime candidate to bring the benefits of technology to the parched lands of Africa.

Supplementing the well water would be collection of runoff rainwater during the rainy season for later use in drought. Southern Africa has its own network of information sharing called SEARNET, which informs farmers of techniques to catch and store rainwater, with some seeing increased yields and additional harvests. [48] This new network of farmers sharing their ideas with each other has led to a spread of both new and old ideas, and this has led to greater sustainability of water resources in the countries of Botswana, Ethiopia, Kenya, Malawi, Rwanda, Tanzania, Uganda, Zambia and Zimbabwe. This water could be used for agriculture or livestock, or could be fed through a purifier to yield water suitable for human consumption.


A solar powered water pump and holding system was installed in Kayrati, Chad, in 2004 as compensation for land lost to oil development. [49] This system utilizes a standard well pump powered by a photovoltaic panel array. The pumped water is stored in a water tower, providing the pressure needed to deliver water to homes in the area. This use of oil revenue to build infrastructure is an example of using profits to advance the standard of living in rural areas.

Hundreds of solar water pumping stations in Sudan fulfill a similar role, involving various applications of different systems for pumping and storage. Over the past 10 years approximately. 250 photovoltaic water pumps have been installed in Sudan. Considerable progress has been made and the present generation of systems appear to be reliable and cost–effective under certain conditions. A photovoltaic pumping system to pump 25 cubic metres per day requires a solar array of approx. 800 Wp. Such a pump would cost US$6000, since the total system comprises the cost of modules, pump, motor, pipework, wiring, control system and array support structure. PV water pumping has been promoted successfully in Kordofan state in Sudan. It shows favorable economics as compared to diesel pumps, and is free from the need to maintain a regular supply of fuel. The only maintenance problems with PV pumping [are] due to the breakdown of pumps and not the failure of the PV devices. [50]

The Solar Water Purifier, developed and manufactured by an Australian company, is a low-maintenance, low operational cost solution that is able to purify large amounts of water, even seawater, to levels better than human consumption standards set by the World Health Organization. [51] This device works through the processes of evaporation and UV radiation. Light passes through the top layer of glass to the black plastic layer underneath. Heat from the solar radiation is trapped by the water and by the black plastic. This plastic layer is a series of connected troughs that separate the water as it evaporates and trickles down through the levels. The water is also subjected to UV radiation for an extended period of time as it moves through the device, which kills many bacteria, viruses, and other pathogens. In a sunny, equatorial area like much of Africa, this device is capable of purifying up to 45 liters per day from a single array. Additional arrays may be chained together for more capacity.

The Water School uses SODIS solar disinfection currently in target areas of Kenya and Uganda to help people drink water free of pathogens and disease causing bacteria. SODIS is a UV process that kills microorganisms in the water to prevent water borne disease. The science of the SODIS system is proven with over 20 years of research. [52]

Wind power

Darling Wind Farm in South Africa Darling Wind Farm.jpg
Darling Wind Farm in South Africa
Wind Speed in Sub-Saharan Africa. Sub-Saharan-Africa-Mean-Wind-Speed-Global-Wind-Atlas.png
Wind Speed in Sub-Saharan Africa.

The Koudia Al Baida Farm in Morocco, is the largest wind farm in the continent. Two other large wind farms are under construction in Tangier and Tarfaya.

Kenya is building a wind farm, the Lake Turkana Wind Power (LTWP), in Marsabit County. As Africa's largest wind farm, the project will increase the national electricity supply while creating jobs and reducing greenhouse gas emissions. LTWP is planned to produce 310 MW of wind power at full capacity. [53] [54]

In January 2009, the first wind turbine in West Africa was erected in Batokunku, a village in The Gambia. The 150 kilowatt turbine provides electrical power for the 2,000-person village. [55]

The South African REIPPP has resulted in several wind farms already in commercial operation in the country. These wind farms are currently in operation in the provinces of the Eastern, Northern and Western Cape. It is estimated that 10 farms are already under construction or in operation, with 12 more being approved with the 4th Round of the REIPPP.

Geothermal power

So far, only Kenya has exploited the geothermal potential of the Great Rift Valley. [15] Kenya has been estimated to contain 10,000 MWe of potential geothermal energy, [56] and has twenty potential drilling sites marked for survey in addition to three operational geothermal plants. [57] Kenya was the first country in Africa to adopt geothermal energy, in 1956, and houses the largest geothermal power plant on the continent, Olkaria II, operated by Kengen, who also operate Olkaria I. A further plant, Olkaria III, is privately owned and operated. [57] [58]

Ethiopia is home to a single binary-cycle plant but does not utilize its full potential energy output for lack of experience in its operation. [15] Zambia has several sites planned for construction but their projects have stalled due to lack of funds. [15] Eritrea, Djibouti and Uganda have undertaken preliminary exploration for potential geothermal sources but have not constructed any type of power plant. [15]

Geothermal power has been used in agricultural projects in Africa. The Oserian flower farm in Kenya utilizes several steam wells abandoned by Kengen to power its greenhouse. In addition, the heat involved in the geothermal process is used to maintain stable greenhouse temperatures. The heat can also be utilized in cooking, which would help eliminate the dependence on wood burning. [59]


Exploration and construction of future geothermal plants present a high cost for poor countries. [60] Drilling potential sites alone costs millions of dollars and can result in zero energy return if the consistency of the heat and steam is unreliable. [61] Return on investments into geothermal power are not as quick as those into fossil fuels and may take years to pay off; however, low-maintenance cost and the renewable nature of geothermal energy mean more benefits in the long term. [60]

As an early and successful adopter of geothermal power, Kenya now has significant financial backing from the World Bank. [58] The country hosts development conferences between representatives of the UN Environment Program and various African governments.

See also

Related Research Articles

Renewable energy Energy that is collected from renewable resources

Renewable energy is energy that is collected from renewable resources, which are naturally replenished on a human timescale, such as sunlight, wind, rain, tides, waves, and geothermal heat. Renewable energy often provides energy in four important areas: electricity generation, air and water heating/cooling, transportation, and rural (off-grid) energy services.

Energy development Methods of energy production from various sources

Energy development is the field of activities focused on obtaining sources of energy from natural resources. These activities include production of conventional, alternative and renewable sources of energy, and for the recovery and reuse of energy that would otherwise be wasted. Energy conservation and efficiency measures reduce the demand for energy development, and can have benefits to society with improvements to environmental issues.

Electric power systems consist of generation plants of different energy sources, transmission networks, and distribution lines. Each of these components can have environmental impacts at multiple stages of their development and use including in their construction, during the generation of electricity, and in their decommissioning and disposal. We can split these impacts into operational impacts and construction impacts. This page looks exclusively at the operational environmental impact of electricity generation. The page is organized by energy source and includes impacts such as water usage, emissions, local pollution, and wildlife displacement.

Sustainable energy Principle of using energy without compromising the needs of future generations

Sustainable energy is the practice of using energy in a way that "meets the needs of the present without compromising the ability of future generations to meet their own needs."

Rural electrification

Rural electrification is the process of bringing electrical power to rural and remote areas. Rural communities are suffering from colossal market failures as the national grids fall short of their demand for electricity. As of 2017, over 1 billion people worldwide lack household electric power – 14% of the global population. Electrification typically begins in cities and towns and gradually extends to rural areas, however, this process often runs into road blocks in developing nations. Expanding the national grid is expensive and countries consistently lack the capital to grow their current infrastructure. Additionally, amortizing capital costs to reduce the unit cost of each hook-up is harder to do in lightly populated areas. If countries are able to overcome these obstacles and reach nationwide electrification, rural communities will be able to reap considerable amounts of economic and social development.

Off-the-grid or off-grid is a characteristic of buildings and a lifestyle designed in an independent manner without reliance on one or more public utilities. The term "off-the-grid" traditionally refers to not being connected to the electrical grid, but can also include other utilities like water, gas, and sewer systems, and can scale from residential homes to small communities. Off-the-grid living allows for buildings and people to be self-sufficient, which is advantageous in isolated locations where normal utilities cannot reach and is attractive to those who want to reduce environmental impact and cost of living. Generally, an off-grid building must be able to supply energy and potable water for itself, as well as manage food, waste and wastewater.

Renewable heat is an application of renewable energy and it refers to the renewable generation of heat, rather than electrical power. Renewable heat technologies include renewable biofuels, solar heating, geothermal heating, heat pumps and heat exchangers to recover lost heat. Significant attention is also applied to insulation.

Renewable energy in Australia

Renewable energy in Australia includes wind power, hydroelectricity, solar PV, heat pumps, geothermal, wave and solar thermal energy.

Renewable energy commercialization

Renewable energy commercialization involves the deployment of three generations of renewable energy technologies dating back more than 100 years. First-generation technologies, which are already mature and economically competitive, include biomass, hydroelectricity, geothermal power and heat. Second-generation technologies are market-ready and are being deployed at the present time; they include solar heating, photovoltaics, wind power, solar thermal power stations, and modern forms of bioenergy. Third-generation technologies require continued R&D efforts in order to make large contributions on a global scale and include advanced biomass gasification, hot-dry-rock geothermal power, and ocean energy. As of 2012, renewable energy accounts for about half of new nameplate electrical capacity installed and costs are continuing to fall.

For solar power, South Asia has the ideal combination of both high solar insolation and a high density of potential customers.

Renewable energy in the United States Renewable energy statistics and policy in the United States

According to preliminary data from the US Energy Information Administration, renewable energy accounted for about 11% of total primary energy consumption and about 17% of the domestically produced electricity in the United States in 2018. Hydroelectric power is currently the largest producer of renewable electricity in the country, generating around 6.5% of the nation's total electricity in 2016 as well as 45.71% of the total renewable electricity generation. The United States is the fourth largest producer of hydroelectricity in the world after China, Canada and Brazil.

Low-carbon power

Low-carbon power comes from processes or technologies that produce power with substantially lower amounts of carbon dioxide emissions than is emitted from conventional fossil fuel power generation. It includes low carbon power generation sources such as wind power, solar power, hydropower and nuclear power. The term largely excludes conventional fossil fuel plant sources, and is only used to describe a particular subset of operating fossil fuel power systems, specifically, those that are successfully coupled with a flue gas carbon capture and storage (CCS) system. Globally, 35% of electricity generation comes from low-carbon sources. As of 2018 the largest low-carbon energy sources globally were hydropower and nuclear power, with the latter providing over 50% of low-carbon power alone in United States and European Union.

Renewable energy in developing countries

Renewable energy technology has sometimes been seen as a costly luxury item by critics, and affordable only in the affluent developed world. This erroneous view has persisted for many years, but 2015 was the first year when investment in non-hydro renewables, was higher in developing countries, with $156 billion invested, mainly in China, India, and Brazil.

Energy in Ethiopia is energy and electricity production, consumption, transport, exportation, and importation in Ethiopia.

Renewable energy debate

Policy makers often debate the constraints and opportunities of renewable energy.

Renewable energy in Italy

Renewable energy has developed rapidly in Italy over the past decade and provided the country a means of diversifying from its historical dependency on imported fuels. Solar energy production alone accounted for around 8% of the total electric production in the country in 2014, making Italy the country with the highest contribution from solar energy in the world. Rapid growth in the deployment of solar, wind and bio energy in recent years lead to Italy producing over 40% of its electricity from renewable sources in 2014.

Renewable energy in Ethiopia

Ethiopia generates most of its electricity from renewable energy, mainly hydropower.

In 2013, renewable energy provided 26.44% of the total electricity in the Philippines and 19,903 gigawatt-hours (GWh) of electrical energy out of a total demand of 75,266 gigawatt-hours. The Philippines is a net importer of fossil fuels. For the sake of energy security, there is momentum to develop renewable energy sources. The types available include hydropower, geothermal power, wind power, solar power and biomass power. The government of the Philippines has legislated a number of policies in order to increase the use of renewable energy by the country.

Renewable energy in South Africa

Renewable energy in South Africa is energy generated in South Africa from renewable resources, those that naturally replenish themselves—such as sunlight, wind, tides, waves, rain, biomass, and geothermal heat. Renewable energy focuses on four core areas: electricity generation, air and water heating/cooling, transportation, and rural energy services. The energy sector in South Africa is an important component of global energy regimes due to the country's innovation and advances in renewable energy. South Africa's contribution to greenhouse gas (GHG) emissions is ranked as moderate and its per capita emission rate is higher than the global average. Energy demand within the country is expected to rise steadily and double by 2025.

Solar augmented geothermal energy Solar augmented geothermal energy provides a method for the production, storage, and subsequent mining of synthetic geothermal energy from solar thermal energy

Solar augmented geothermal energy (SAGE) is an advanced method of geothermal energy that creates a synthetic geothermal storage resource by heating a natural brine with solar energy and adding enough heat when the sun shines to generate power 24 hours a day. The earth is given enough energy in one hour to provide all electrical needs for a year. Available energy is not the issue, but energy storage is the problem and SAGE creates effective storage and electrical power delivery on demand. This technology is especially effective for geothermal wells that have demonstrated inconsistent heat or idle oil or gas fields that have demonstrated the proper geology and have an abundance of solar.


  1. 1 2 "Global Solar Atlas" . Retrieved 6 December 2018.
  2. The Human Development Report 2001, United Nations Development Programme
  3. Nations, United. "The Role of Fossil Fuels in a Sustainable Energy System". United Nations. Retrieved 30 May 2020.
  4. Nuclear Energy and the Fossil Fuels Archived 27 May 2008 at the Wayback Machine , M.K. Hubbert.
  5. Annual Report Archived 7 October 2007 at the Wayback Machine , Page 2, Eskom (2006)
  6. Letter to International Finance Corporation, Woicke P. (2000)
  7. Expanding Electricity Access to Remote Areas: Off Grid Rural Electrification in Developing Countries, Reich et al. (2000)
  8. Malawi District Energy Officer Blueprint: Recommendations Paper, Buckland et al. (2017)
  9. Wikipedia article on orders of magnitude (energy)
  10. Alternative energy sources for electricity generation: Their 'energy effectiveness' and their viability for undeveloped and developing countries Archived 13 June 2007 at the Wayback Machine , Jobe Z. (2006)
  11. "Africa urged to reap its alternative energy". Retrieved 2 April 2019.
  12. Louis Boisgibault, Fahad Al Kabbani (2020): Energy Transition in Metropolises, Rural Areas and Deserts. Wiley - ISTE. (Energy series) ISBN   9781786304995.
  13. Report on Solar Power Potential Archived 27 September 2007 at the Wayback Machine , German Aerospace Center
  14. 1 2 "Global Wind Atlas" . Retrieved 7 December 2018.
  15. 1 2 3 4 5 6 "Geothermal Potential in East Africa". Archived from the original on 19 June 2007. Retrieved 7 June 2007.
  16. Background Information, Sahara Wind.
  17. Cassedy, Edward S. Prospects for Sustainable Energy: A Critical Assessment. New York Cambridge UP, 2000.
  18. African Wind Energy Association Summary Archived 22 May 2007 at the Wayback Machine
  19. Malin P.E (2001) Establishment of Geothermal Resource Center to Accelerate the Development of Eastern Africa
  20. Energy in Africa, Chapter 7, United States Energy Information Administration "U.S. Energy Information Administration (EIA)". Archived from the original on 16 June 2007. Retrieved 16 June 2007.
  21. Building a Sustainable Energy Base (NEPAD Platform)
  22. Benefits of clean fuel in Africa would be enormous, Kevin Myron, Harvard Gazette Archives
  23. Prospects for Distributed Electricity Generation, Congressional Budget Office (2003)
  25. Africa Regional Findings (2001) Rural Electrification: Lessons Learned, World Bank
  26. Britain Urges Global Carbon Trading To Spur Eco-Healthy Growth, Aziakou G. (2006)
  27. Sustainable Energy Finance Activity Overview, UNEP (2006)
  28. Good intentions: the mismanagement of foreign aid, Heckt J.L (1996)
  29. Solar loan program in India
  30. Solar loan programme, kenya Archived 15 July 2007 at the Wayback Machine
  31. UNEP on climate change
  32. UNEP REED fund Archived 7 August 2007 at the Wayback Machine
  33. South African Renewables Initiative
  34. Frequently Asked Questions on Renewable Energy and Energy Efficiency, Body of Knowledge on Infrastructure Regulation,
  35. "Global Solar Atlas" . Retrieved 7 December 2018.
  36. Nji, Renatus. 2006. What alternatives to oil in Africa? Africa Renewal. Vol.20. p. 17.
  37. In Rwanda, Israelis and Americans launch East Africa’s first commercial solar field, Jeruslaem Post, 6 February 2015
  38. "Rwanda: rays of sunshine for the economy". Deutsche Gesellschaft für Technische Zusammenarbeit (GTZ) GmbH. 2007. Retrieved 22 March 2010.
  39. "Archived copy". Archived from the original on 9 August 2013. Retrieved 17 August 2013.CS1 maint: archived copy as title (link)
  40. "Archived copy". Archived from the original on 7 August 2013. Retrieved 17 August 2013.CS1 maint: archived copy as title (link)
  41. "Archived copy". Archived from the original on 18 January 2015. Retrieved 12 January 2015.CS1 maint: archived copy as title (link)
  42. "Archived copy". Archived from the original on 7 January 2015. Retrieved 12 January 2015.CS1 maint: archived copy as title (link)
  43. "Archived copy". Archived from the original on 8 April 2011. Retrieved 18 February 2011.CS1 maint: archived copy as title (link)
  44. Power Up Gambia
  45. Energy For Opportunity (2011). "Energy For Opportunity: Annual Report 2010" (PDF). EFO: Sierra Leone.[ permanent dead link ]
  46. Simon Willans, Amé Christiansen and Paul Munro (2011). "Emerging Forms of Entrepreneurship: For-Profit and Non-Profit Partnerships for the Dissemination of Solar Power into Rural Sub-Saharan Africa" (PDF). Paper presented at the 56th Annual ICSB World Conference: Sweden.
  47. Kemeny, P; Munro, P G; Schiavone, N; van der Horst, G; Willans, S (2014). "Community Charging Stations in rural sub-Saharan Africa: Commercial success, positive externalities, and growing supply chains". Energy for Sustainable Development. 23: 228–236. doi:10.1016/j.esd.2014.09.005.
  48. Moyo, S. and Nyimo, T. 2006. Regional Annex Rainwater Harvesting in Southern Africa. The WELL resource centre for water, sanitation and environmental health.
  49. CHAD: Trying to make oil wealth work for the people, UN Office for the Coordination of Humanitarian Affairs
  50. Omer, Abdeen Mustafa. 2000. Solar water pumping clean water for Sudan rural areas. Renewable Energy Vol. 24. (pp.245–258)
  51. How SWP Works, Solar Water Purifier website, 2007
  52. "solar disinfection sodis: Topics by". Retrieved 30 May 2020.
  53. "LEDS in practice: Massive wind power project to benefit Kenya". Low Emission Development Strategies Global Partnership (LEDS GP) . Retrieved 12 July 2017.
  54. "Lake Turkana Wind Power – LTWP" . Retrieved 2 April 2019.
  55. Dierk Jensen (March 2009). "A Second Life in Africa". New Energy Magazine. Retrieved 24 June 2009.
  56. "Archived copy". Archived from the original on 5 November 2013. Retrieved 6 August 2013.CS1 maint: archived copy as title (link)
  57. 1 2 "Archived copy". Archived from the original on 10 December 2007. Retrieved 29 December 2008.CS1 maint: archived copy as title (link), International Geothermal Association
  58. 1 2 Geothermal Potential in Kenya Archived 12 June 2007 at the Wayback Machine
  59. Kenya Looks Underground for Power, BBC
  60. 1 2 Geothermal Energy
  61. "Kenya looks underground for power". 22 April 2005. Retrieved 2 April 2019.