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Renewable energy in South Africa is energy that is obtained from renewable resources, those which naturally replenish themselves, such as; sunlight, wind, tides, waves, rain, biomass, and geothermal heat. Renewable energy focuses on four core areas including; 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.
Of all of the renewable energies in South Africa, solar power holds the most potential. Because of the country's geographic location, it receives large amounts of radiative energy which is useful in the solar electricity sector. Another renewable energy in South Africa with high potential is wind energy. Due to the high wind velocity on the coast of the country, Cape Town has implemented multiple wind farms which are successful in generating significant amounts of electricity for residents. Renewable energy systems in the long-term are comparable or cost slightly less than non-renewable sources. Biomass is currently the largest renewable energy contributor in South Africa with 9-14% of the total energy mix. Renewable energy systems are costly to implement in the beginning but provide high economic returns in the long-run.
The two main barriers accompanying renewable energy in South Africa are; the energy innovation system, and the high cost of renewable energy technologies. The Renewable Energy Independent Power Producers Procurement Programme (REI4P) suggests that the cost associated with renewable energy will equal the cost of non-renewable energy by 2030. Renewable energy is becoming more efficient, inexpensive, and widely used. South Africa has an abundance of renewable resources that can effectively supply the country's energy.
South Africa is now a member of the International Renewable Energy Agency (IRENA) which is an international organization that promotes the use of renewable energy policies. The IRENA aims at providing countries with tools to create policies and the transition of technology necessary for renewable energy. It provides an assessment of resources, finance management, policy and legal framework and the capacity of the energy sector.
The National Energy Regulator of South Africa (NERSA) implemented the Renewable Energy Feed-In Tariff (REFIT) in 2009. The REFIT works to progressively reduce carbon-based power generation by moving in the direction of renewable energy sources. NERSA employed the REFIT in an attempt to meet the target of producing 10TWh of electricity by 2013. When first introduced, the feed-in tariffs applied only to wind energy, hydropower, and concentrated solar power (CSP). Six months after the introduction, the tariffs were expanded to include biomass and solar photovoltaics. The organization wants to achieve sustainability through the use of renewable resources while engaging stakeholders, lowering the cost of investment, and making the cost of electricity more affordable for all. The decentralized investment opportunity provides South Africa with the resources to overcome its current energy crisis. REFIT is the first successful greenhouse gas mitigating projects used in South Africa. The REFIT program was superseded by the Renewable Energy Independent Power Producers Procurement Programme in May 2011.
South Africa first introduced the Renewable Energy Independent Power Producers Procurement Programme (REI4P) in 2011. The program includes an initiative to install 17.8GW of renewable energy in South Africa before 2030. The goal of the REI4P is to reduce greenhouse gas emissions while minimizing the country's reliance on non-renewable energy sources such as nuclear and coal. REI4P also works to promote local manufacturing of materials used in the renewable energy sector.
To incentivize the further rollout of renewable energy generation by the private sector, the South African Revenue Service has of 1 January 2016 amended the Income Tax Act No. 58 of 1962 to include accelerated depreciation for renewable energy assets commissioned by a tax paying entity. This tax incentive is not limited to new renewable generation systems.
A special provision is made for photovoltaic systems that are smaller or equal to 1 MWp (Megawatt peak) in section 12 B of the Tax Act allowing the system to be depreciated according to the following schedule:
- Year 1: 100% depreciation
By depreciating the photovoltaic solar system by 100% in year one the tax paying entity is granted a tax shield due to saved income tax. This results in a 28% discount on the photovoltaic solar system. The tax shield applies even if the photovoltaic solar system is installed mid-year. By partially financing the photovoltaic solar system through debt, systems can achieve a repayment time of 1 year. Systems subsequently achieve ongoing electricity savings for each year of operation.
Wind power, concentrated solar power (CSP), biomass, photovoltaic systems exceeding 1 MWp, hydropower not exceeding 30 MW as well as biomass systems are also incentivized through an accelerated depreciation with the following schedule:
- Year 1: 50% depreciation
- Year 2: 30% depreciation
- Year 3: 20% depreciation
Main article: Solar power in South Africa
Solar energy is light and heat that is radiated from the Sun. It is then transformed into electricity through photovoltaics (PV) or concentrated solar power (CSP). Solar energy in South Africa is primarily based in PV and CSP. The levelized cost of solar electricity is relative to the quality and quantity of solar radiation in South Africa. The same plant can produce up to 20% more electricity for the same capital investment in South Africa compared to countries in Europe. The furthest area in the west of the country receives the highest levels of solar radiation, ranging from 2100 kWh/m2 to more than 2300 kWh/m2. Solar power production in South Africa is supposed to reach 8400 MW by the year 2030. South Africa implemented a solar park in the Northern Cape region which is set to deliver 180,000MWh of annual solar energy to the country. It is estimated that only 3000 km^2 of land used for solar electricity is required to meet South Africa's demand.
Solar energy is a low-cost source of energy compared to traditional non-renewable energy resources in South Africa. The introduction of solar power plants has stimulated the economy and created jobs within the country. South Africa's land cover receives an average of 2,500 hours of sunshine per year. Solar energy systems have a high initial cost, but typically return the investment within 5 to 8 years. The use of solar energy in South Africa is driving the use of other renewable energy sources including wind, hydroelectric, and biomass.
Wind power is the use of wind turbines to mechanically power the generation of electric power. Levels of wind will differentiate depending on factors such as terrain, bodies of water and vegetative cover. Wind turbines convert the wind into kinetic energy and mechanical power. The wind turns the 50-metre-long blades which are attached to the 80-metre-high hub/shaft that generate the electric energy. Wind turbine farms can range between 10MW to over 100 MW and produce energy when the wind is between 13–90 km/h. Wind turbines farms can be onshore or offshore; offshore have stronger winds and less of a visual impact. In 2014 the first major wind farm became operational with approximately 10 either operational or in construction today. South Africa's extensive coastline and geographical terrain including lowlands and high veld escarpment, provide wind energy that can be extracted and generated into off-the-shelf technology. There are currently 19 wind energy developments in South Africa with more than 600 wind turbines. On the international scale, South Africa ranks as having fair to reasonable wind resources. Wind power is a renewable, widely distributed and clean form of energy. The production of wind energy does not produce greenhouse gases and is an alternative to burning fossil fuels.
Hydropower, or hydroelectric power, is energy that is captured from flowing water and turned into electricity. The most common forms of hydropower use hydroelectric dams to create a reservoir for storing water. When the water is released from the reservoir, it flows through a turbine which generates electricity. South Africa currently has 7 hydroelectric power stations, dispersed across the country, all owned by Eskom. The country's hydroelectricity potential is limited due to the low annual rainfall rate of 500mm. South Africa experiences seasonal flows and frequent droughts which are obstacles to the success of hydropower within the country. The Eastern Cape province is considered the hydro-potential of the country. Hydroelectric dams in South Africa can be associated with other water uses, such as irrigation and flood control, to increase economic development within the country. The current installed capacity within the country is 668MW. Large-scale (>10MW) hydroelectric generation systems have the potential to contribute up to 5091MW of energy, but can have negative implications on the environment. The large amount of flowing water can damage river ecology, and the facilities take up a significant amount of land space. Small-scale (<10MW) hydroelectric generation systems can contribute up to 69MW of energy and do not have any major environmental implications.
Biomass is physical biological material that comes from living or recently living organisms. It comes from plants or materials that are derived from plants which are called lignocellulosic biomass. Biomass has the capacity to produce electricity, heat or liquid fuels. Biomass can be used as an energy source by directly using it for heating or cooking fuel or to generate electricity. It can also be used indirectly by using its biological processes and producing ethanol, methanol and fuel that can be used to transportation and cooking processes. Wood is currently the largest producer of biomass fuel today with tree stumps, forest residue, dead trees and wood chips as examples. Animal matter and plant matter can also be converted into forms of biofuel. South Africa currently has several biodiesel production facilities in production. With 42 million hectares of natural woodlands and 1.35 million hectares of plantation; there is a large potential for biomass production in South Africa. The South African government has an objective called the Working for Energy Programme which is aimed at processing biomass energy for various applications.
Geothermal energy is generated from heat that is stored in the Earth. The geothermal energy is that is generated from the Earth's crust is the original formation of the planet and from radioactive decay of material. Geothermal heat pumps tap into the ground to use this resource as a source of energy. The production of geothermal energy is a clean and sustainable form of energy. There are currently no geothermal energy practices in South Africa but there are projects underway to implement them. Geothermal measurements have been made throughout South Africa, demonstrating that there is high geothermal potential and that the relevant temperatures rank from medium to high on the global scale.
The South African energy sector is dominated by the company Eskom. Eskom currently produces 95% of South Africa's electricity. Due to their large presence in the non-renewable energy sector, there are independent power producers (IPP) who are capable of providing renewable energy sources. In order to reach the 10,000 GWh target of renewable energy, the government has joined agencies and implemented policies to promote independent power producers in implementing renewable energy. BioTherm Energy is the leading IPP because of their three wind and solar projects that are involved in REI4P. Mulilo is a South African company who provides clean energy such as wind and solar to the national grid. Mulilo is a member of the South African REI4P and has won 420MW worth of projects. They currently have 30MW of solar PV operational and have another 185MW scheduled. By the end of 2017 Mulilo will have 240MW for wind power contributions. juwi South Africa is a renewable energy company who is also one of the world's leading renewable energy companies. juwi South Africa's main focus is on the production of solar energy on a utility and commercial scale, as well as onshore wind energy. juwi South Africa has built five utility-scale solar plants under the REI4P and they are also a member of the IPPs.
South Africa is one of the most popular countries for investment in renewable energy. In 2014, the country received US$5.5 billion towards renewable energy projects. Renewable energy in South Africa has the potential to increase access to electricity in rural areas because of its suitability for off-grid and small-scale solutions. The barriers of renewable energy in the country include lack of political stability and capacity, marginalization, corruption, poverty, and environmental degradation. The government introduces both short-to-medium and long-term targets to help set the pace of renewable energy production.
A financial barrier exists in the renewable energy sector in South Africa. Investors choose to invest in large-scale non-renewable resource companies, such as Eskom, rather than Independent Power Producers such as BioTherm, Mulilo, and juwi South Africa. The high initial capital required to employ renewable energy is a large constraint the sector experiences.
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