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Renewable energy in Finland increased from 34% of the total final energy consumption (TFEC) in 2011 to 48% by the end of 2021, primarily driven by bioenergy (38%), hydroelectric power (6.1%), and wind energy (3.3%). In 2021, renewables covered 53% of heating and cooling, 39% of electricity generation, and 20% of the transport sector. By 2020, this growth positioned Finland as having the third highest share of renewables in TFEC among International Energy Agency (IEA) member countries.[1]
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In 2020, Finland's share of renewables in gross final energy consumption reached 44.6%, surpassing the target of 38%. This excess enabled Finland to sell statistical transfers of renewable energy to EU member states not meeting their 2020 targets. In March 2021, Finland agreed to a transaction with Belgium, selling 1,376.5 GWh of renewable energy for EUR 18.6 million. After this sale, Finland's renewable energy share in gross final consumption was reported at 43.8%, still above the 2020 goal.[1]
Finland's climate strategy, aimed at carbon neutrality by 2035, focuses on increasing energy efficiency and advancing technological innovations, especially in sustainable hydrogen solutions for heavy transport and industry. According to data from 2021, Finland's energy supply was less dependent on fossil fuels compared to many other countries, with only 36% coming from these sources, significantly lower than the International Energy Agency's average of 70%. The emphasis in Finland's energy mix has been on renewable sources like biomass, hydro, and wind power. These measures are part of Finland's efforts to decrease energy intensity and improve energy security.[2]
According to the International Energy Agency's (IEA) 2023 Energy Policy Review, Finland saw a notable increase in its total final energy consumption (TFEC) from renewable sources, growing from 34% to 48% between 2011 and 2021. This increase was driven by a growth in bioenergy from 29% to 38% of TFEC, hydroelectric power from 4.7% to 6.1%, and wind energy from 0.2% to 3.3%. By 2020, Finland's share of renewables in TFEC ranked third highest among the 31 IEA member countries.[1]
In 2021, renewable energy accounted for 43% overall, 39% in electricity, 53% in heating and cooling, and 20% in transport. For 2030, renewable energy targets have been set at 51% overall, with specific aims of 53% in electricity, 61% in heating and cooling, and 45% in transport.[1]
Finland differs from most industrialized countries in that many of its energy needs stem from the Nordic conditions. Finland is located between 60 and 70 degrees northern latitude and a quarter of its area lies north of the Arctic Circle. In fact, one third of all people living north of the 60th parallel are Finns. The annual mean temperature in the south of the country is around 5 °C and 0 °C in the north. The population-weighted average number of heating degree days for Finland is 5000, considerably more than in Sweden and Norway (4000). Thus, the Finnish climate is the coldest in the EU and, consequently, a large share of the energy (22%) is used for the heating of buildings.[3]
Finland's energy consumption increased 44% in electricity and 30% in total energy use during the period 1990–2006. The increase in electricity consumption of 15,000 GWh (1995–2005) was more than Finland's total hydroelectric power capacity. The consumption increased almost equally in all sectors (industry, residential, and services). The share of renewable electricity in Finland has been stable (1998–2005): 11-12% plus yearly variable hydroelectric power, totaling 24-27%. The forest industries contributed 57% of the RE power generation via black liquor and wood burning in 1990. By 2005 this share had grown to 67%.[4] The rest consisting primarily of hydroelectric power. As with most first world countries, the vast majority of commercially viable hydroelectric sites in Finland have already been developed. The forest industry uses 30% of all electricity in Finland (1990–2005). Its process wastes, wood residues, and black liquor were used to produce 7-8000 GWh of electricity in 2005. However, during that year electricity consumption fell 10% compared to 2004 as a result of a prolonged forest industry labour dispute.[5] Finland's power consumption was (2005) 17.3 MW electricity per capita compared to Germany 7.5 MW per capita. This number includes the power losses of the distribution.
According to the International Renewable Energy Agency (IRENA), Finland's renewable energy sector in 2020 was predominantly fueled by bioenergy, which accounted for 81% of the renewable energy supply. Hydro/marine sources contributed 12%, wind power made up 6%, and geothermal sources added 1%, with solar energy contributions not explicitly mentioned.[6]
Finnish CO2 emissions grew 14.5% (1990:2004), while the EU average was - 0.6%.[7]
The Finnish energy policy is based on the National Climate Strategy of 2001, updated in 2005 and 2008. The strategy provides the basis for policy preparation, decision-making and negotiations on national, EU and international levels. In its most recent adaptation, the strategy focuses on setting guidelines up to 2020 and a vision as far as 2050 to steer long-term planning.
The aim is to fulfil the Kyoto Protocol and its obligations by 2013. By that time, adequate post-Kyoto emission reduction measures should be in place, including the set of measures required of EU countries by 2020 by common agreement. To that end, the EU requires its members to report by 2016 about their ability to meet the obligations set for 2020. With regard to renewables, the EU goals aim to a share of 38% of final energy consumption in Finland by 2020, compared to 28.5% in 2005 and a previous national goal of 31% by 2020.
The national long-term vision aims at halting the growth of final energy consumption on one hand, and increasing the share of renewables on the other hand. To attain these objectives, the energy efficiency of consumption must be enhanced, particularly in housing, construction and transport, and new policy measures must be enacted to promote renewables.
The government expects the growing global demand of fossil fuels to drive their prices further up in the long term. Combined with the cost of emission allowances, this will significantly change the price relationship of fossil and renewable energy in favour of the latter. The government envisions significant growth in the use of wood-based energy, waste fuels, heat pumps, biogas and wind energy. A feed-in tariff system will be introduced as a major new policy measure to drive the introduction of renewables.
Other major points in the strategy include:
Finland already has among the highest shares of renewables, yet Finland for a long time did not use feed-in tariffs, fixed premiums, green certificate systems or tendering procedures. Lately some new policies have been adopted. From the European countries, Finland, Malta and Slovenia are the only ones (2006) that use only tax incentives to promote wind energy and other renewable electricity. Finland has no obligations or binding recommendations for the power companies to promote RE.[8]
Finland was one of the few that opposed the sustainability criteria of biofuels in the EU in 2013.[9]
Energy markets in Finland are based on free enterprise and open competition. The electric power industry in Finland has been open for competition since the new electricity market legislation in 1995. At the same occasion Finland joined the joint Nordic electricity market area where spot prices for electricity are determined at the common electricity exchange Nordpool. Power can be bought and sold freely in Finland, Sweden, Norway and most parts of Denmark.
For district heat there is no national market for technological reasons, as heat cannot be transported over long distances. However, district heat is largely produced by the same energy companies in centralised district heating plants or CHP plants. Locally there is usually only one district heat provider available, which means that the competition takes place between alternative heat sources. Biomass fuels and peat are commonly used for district heating. Some district heat is also sold in small scale by local entrepreneurs who produce it with biomass fuels. The government company for promoting energy efficiency, Motiva, has a program for promoting small scale heating entrepreneurship.
In the Nordic electricity market, each country is independently responsible for its transmission grid. In Finland the local distribution grids are owned primarily by local energy companies. The national transmission grid is owned by the Fingrid corporation which for its part is owned jointly by the state, energy companies and financial investors. Major changes in the ownership of Fingrid are expected as new EU legislation will forbid energy producers from owning parts of the transmission grid.
The largest electricity producers in Finland are Fortum, the state energy company, Pohjolan Voima, the energy company owned by major industries, Teollisuuden Voima, the industry-owned nuclear power company, Helsingin Energia, the power company of Helsinki City, and Vattenfall, the largest energy company of Sweden. There are also a large number of small and medium-sized local energy companies. A special feature of the Finnish electricity markets is companies like Pohjolan Voima and Teollisuuden Voima that operate with the Mankala-principle. That is, they do not pay dividends, but rather provide power to their owners without seeking profit.
Moreover, many of the industrial corporations are themselves major energy producers as in a number of factories process wastes are used as fuels. In most cases such fuels originate from wood processing and, therefore, count as renewables. Thus major producers of bioenergy in Finland include all the major wood and paper industry corporations: Stora-Enso, UPM and M-Real. Furthermore, the national oil company, Neste Oil, is a growing producer of biofuels and biodiesel in particular.
Largest hydropower producers are the state-owned companies Fortum and Kemijoki and the industry-owned Pohjolan Voima. The largest producer of wind power in Finland is the Hyötytuuli corporation, owned by the energy companies of various cities. Hyötytuuli produces about one third of wind power in Finland. The rest is produced by a large number of companies in relatively small power plants. Finland is a growing producer of RES related technology. The volume of trade of all energy technology to and from Finland is shown in Figure 4. RES technologies hold a significant share of this trade.
The largest producers of RE technology in Finland include
Smaller companies that produce energy-related clean technology include Aidon, Bearing Drive Finland, DGT Direct Granulation Technology, EcoSir, Finnish Electric Vehicle technologies, Greenvironment, Modilis, Primet, Puhdas Energia and The Switch.
Energy efficiency in Finland is advanced by the state-owned company Motiva. Public funding for the development of new technologies is primarily distributed by the Finnish Funding Agency for Technology and Innovation Tekes.
In total electricity and district heat production employed 14,000 people and oil refining and distribution 13,500 people out of the 2,500,000 people employed in Finland in 2003. Bioenergy sector employed an estimated 6000-7000 people. The total employment in the energy sector numbered 34,000 people in 2004. These numbers include renewable and non-renewable energies as there are no separate statistics.
The major renewable energy sources, namely hydropower and bioenergy are produced in a large scale, where business models and jobs are similar to other large-scale energy production. There is additionally small scale production of renewable energy that tends to generate small enterprise and a proportionally greater number of jobs.
For example, the Ministry of Employment the Economy has conducted a research that found that there are 368 small bioenergy companies that provide 1,667 jobs. The number of companies and jobs has grown steadily in the past years and the growth is expected to continue given the ambitious goals for bioenergy in the national climate and energy strategy.
Given that there is established production of wind power plants and plant components, the increased use of wind power in Finland and elsewhere can be expected to create jobs in the sector. This would generate demand for professionals of all levels in mechanical, material and electrical technology. Similar demand can be expected from the increased use of bioenergy and the production of the necessary power plant components.
Professionals in chemistry and life sciences and related fields will be needed for the envisioned development and production of the next generation of biofuels. They will also have an important role in developing the forest industry towards more versatile biorefineries instead of traditional pulp and paper mills.
Finally the strengths of the Finnish electronics industry and education can give rise to a variety of clean technologies such as solar power, control systems for power production and consumption, electric vehicles, etc.
Bioenergy, closely associated with Finland's forestry and forest industry, plays a significant role in the country's renewable energy portfolio. Wood-based fuels, derived from forest industry by-products such as black liquor, bark, sawdust, and industrial wood residues, along with biomass from logging operations, have constituted approximately one quarter of Finland's energy consumption in recent years. By 2022, these fuels accounted for nearly 29 percent of the total energy consumption, establishing wood fuels as the predominant energy source in Finland.[10]
Biomass is widely used as a fuel in electricity production, CHP plants and district heating, often mixed with other fuels, especially peat. In fact, Finland is among the world leaders in the use of CHP. Both renewable and fossil fuels are used. The world's largest bio power plant with a capacity of 265 MW is situated in Jakobstad in Finland. Wood is also used directly for heating. In total around 6 million m3 or 50 PJ of firewood are used annually for space heating. There are also dedicated boilers that burn wood chips or pellets. Fuel oil fired heating can be converted to use pellets, which has been estimated to have a potential of 25 PJ/a.[3]
Agricultural biomass production takes place on a modest scale. Annually around 6000 tons of straw is used as a fuel, while theoretically a maximum of 1.8 million tons could be used. Furthermore, turnip rape is cultivated on about 860 hectares mainly for lubrication oil and diesel oil production. Finally, there is some interest in the possibility of growing reed canary grass for use as a fuel. Some tests have been carried out in its use in multifuel boilers and as a raw material for pellets.
Finland uses insignificant wood pellet quantities for thermal energy production. In Sweden and Denmark active energy politics with significant taxation of fossil energy has encouraged an early development of the pellet market. This development has taken place much faster than in Finland where economic incentives are missing, and competing sources of energy are cheap.
Pellet production was 192,000 tons (2005). Pellet consumption was 55,000 t (2005), 47,000 t (2004), 39,000 t (2003), 24,000 t (2002) ja 15,000 t (2001). The pellets are mainly exported. Finland has no binding objectives for pellet use promotion.[4]
The European Union has the objective of 5.75% of biofuels (2010). The biofuels report do not include the Finnish objective.[13] They are not published yet. The Finnish Ministry of Trade and Industry report (KTM 11/2006) admits that Finland would not be able to fulfill the 5.75% objective. The ministry report does not recommend it, because of its expenses. The production price of biofuels in Finland would be equal to other EU countries, 3 cents per liter.[14]
The Finnish parliament did not consider bioethanol competitive in Finland. The director of Altia resigned as Altia's major bioethanol project failed; increased costs made it unprofitable. However, St1 produces bioethanol from food industry wastes.
Neste Oil produces 0.34 million tons per year renewable diesel (NExBTL) by vegetable oil refining in its Porvoo refinery. Currently the main feedstock is palm oil. The public transportation in the Helsinki metropolitan area uses NExBTL. The pulp and paper company UPM is in the process of starting biodiesel production from tall oil. However, a number of projects for biodiesel production have been cancelled due to poor profitability.[15] Finnish government supports biodiesel use financially.[16]
Finnish company Neste Oil biodiesel production capacity in Singapore is 2.9 million tons. After 2022, the new capacity is predicted to be 1.3 million tons more. Neste oil predicts that the world biodiesel demand will be 20 million tons in 2030, and its own production will be half of this. Neste believes there will be an increased demand for airplane fuels. A 10 to 15 percent increase in biodiesel demand in Europe and the US would be equal to 8-12 million tons fuel per year. In 2019, annual fossil biodiesel consumption is estimated to be as much as 900 million tons. According to McKinsey, the fossil biodiesel consumption will not reduce by 2030.[17]
Neste biodiesel is mainly based on palm oil process wastes. Finland has classified palm oil fatty acid residues as sustainable. The WWF approves certified palm oil. In Europe at least, Sweden, Norway, Britain and France do not approve palm oil fatty acid residues (PFAD) as waste and sustainable bioenergy. According to Greenpeace, its use accelerates deforestation.[18]
The palm oil biodiesel has higher climate change gas emissions compared to fossil diesel when the rain forest loss is included and palm oil fat should not be classified as sustainable waste. It is a product sold in markets as raw material. According to Neste, spoil advertisement palm oil biodiesel production chain includes crimes, corruption and human right violations. One of the Neste Oil palm oil providers Bilmar is responsible in rain forest deforestation. [19]
In 2022, hydropower constituted 16.3 percent of Finland's total electricity generation, with an installed capacity of 3,200 MW. Projections indicate little change in hydropower capacity in the foreseeable future.[10]
Wind power in Finland has been the fastest growing source of electricity in recent years. In 2023, Finland covered 18.2% of the yearly electricity demand with wind power production, which was 18.5% of the domestic production. Wind capacity was up 1.3 GW from the previous year and wind production up 25%.[20] This compares to an average wind power share of 19% in the EU.[21]
By the end of 2022, Finland's wind power capacity reached 5,677 MW with 1,393 turbines installed. That year, wind power production increased by 41% to 11.6 TWh, representing 14.1% of the country's electricity consumption. This growth positioned wind power as the country's third largest electricity source.[22]
According to a 2018 study done by VTT Technical Research Centre of Finland, published in Nature Energy, new wind power technology could cover the entire electricity consumption (86 TWh) of Finland.[23]
Wind power is one of the most popular energy resources among the Finnish public. In 2022 82% of respondents wanted more wind power, which was second only to solar with 90%.[24] Previous results include 90% in September 2007 and 88% in April 2005.[25] In the Pori area of Finland 97% of people supported wind power according to Suomen Hyötytuuli Oy in 2000.[26]Despite its northern position, Finland enjoys similar levels of annual sunshine to Germany or Denmark. Lower atmospheric temperatures in Finland enhance solar photovoltaic cell efficiency, as these cells operate more effectively in colder conditions. Nonetheless, solar energy faces technical challenges due to its intermittency, particularly in the Arctic region with its pronounced day-night and seasonal variations. In 2022, Finland's solar power capacity grew by over 60 percent, yet it remains a minor component of the country's overall power generation.[10]
The PV capacity of Finland was (2006) 4.1 MWp. Solar power in Finland was (1993–1999) 1 GWh, (2000–2004) 2 GWh and (2005) 3 GWh.[27] There has been at least one demonstration project by the YIT Rakennus, NAPS Systems, Lumon and City of Helsinki in 2003. Finland is not a member either in the IEA's Photovoltaic Power Systems Programme or the Scandinavian Photovoltaic Industry Association, SPIA.
The objective in solar heating is 163,000 m2 collector area (1995–2010).[28] In 2006 the collector area in operation was 16,493 m2.[29] Solar heat in Finland was (1997–2004) 4-5 GWh and (2005) 6 GWh.[27] Thus, Finland has installed 10% of its objective in 11 years time (1995–2010). The solar heating has not been competitive due to cheap alternatives (electricity, fuel oil and district heating) and the lack of support systems. Companies and public organizations may receive 40% investment subsidies, but private houses do not receive subsidies yet. The Finnish Solar Industries (FSI) group was established in 2001.[28] 2006/2005 the markets grew 43%. Finland's production capacity is 16,000 m2/a. New installations were: 2,380 m2 (2006), 1,668 m2 (2005) and 1,141 m2 (2004). There are growth opportunities in the solar heating.
According to European Union and IPCC peat is not biofuel as claimed but have equal CO2 emissions to coal.[30] The EU also promotes the protection of swamps from ecological disasters. The Finnish peat company Vapo Oy is owned by the state (50.1%) and the forest industry company Metsäliitto (49.9%) (including Metsä-Botnia, M-real and Metsä Tissue and previously also Finnforest). They want to use the peat as fuel and dry the swamps as forests.[31] Scandinavian peat was formed 10,000 years ago after the ice age. In 2005 the European common carbon dioxide emission system was agreed, and according to the agreement peat is equal to fossil fuel.[32]
Many peat energy plants can use coal as alternative energy source.[33]
Renewable electricity consumption (GWh)[34][35][36] | |||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|
Year | Electricity | Non-RE | Non-RE growth % |
RE | RE % | RE without water% |
Water | Wind | Black L | Wood | Other RE |
1990 | 62,334 | 45,882 | 0.0 | 16,452 | 26.4 | 9.1 | 10,752 | 0 | |||
1991 | 62,288 | 43,371 | -5.5 | 18,917 | 30.4 | 9.4 | 13,066 | 1 | |||
1992 | 63,196 | 42,467 | -7.4 | 20,729 | 32.8 | 9.1 | 14,957 | 2 | |||
1993 | 65,545 | 45,372 | -1.1 | 20,173 | 30.8 | 10.4 | 13,343 | 4 | |||
1994 | 68,257 | 49,238 | 7.3 | 19,019 | 27.9 | 10.8 | 11,663 | 7 | |||
1995 | 68,946 | 50,068 | 9.1 | 18,878 | 27.4 | 8.8 | 12,788 | 11 | |||
1996 | 70,018 | 51,915 | 13.1 | 18,103 | 25.9 | 9.1 | 11,704 | 11 | |||
1997 | 73,603 | 54,334 | 18.4 | 19,269 | 26.2 | 10.2 | 11,795 | 17 | |||
1998 | 76,630 | 53,585 | 16.8 | 23,045 | 30.1 | 10.8 | 14,777 | 23 | |||
1999 | 77,779 | 56,398 | 22.9 | 21,381 | 27.5 | 11.4 | 12,547 | 49 | |||
2000 | 79,158 | 56,482 | 23.1 | 22,676 | 28.6 | 10.4 | 14,453 | 77 | 5,126 | 2,920 | 101 |
2001 | 81,188 | 60,301 | 31.4 | 20,887 | 25.7 | 9.7 | 13,018 | 70 | 4,765 | 2,886 | 149 |
2002 | 83,542 | 64,377 | 40.3 | 19,165 | 22.9 | 10.2 | 10,623 | 63 | 5,140 | 3,194 | 144 |
2003 | 85,229 | 66,871 | 44.7 | 18,358 | 21.5 | 10.4 | 9,455 | 92 | 5,255 | 3,389 | 189 |
2004 | 87,041 | 62,239 | 35.7 | 24,802 | 28.5 | 11.4 | 14,865 | 120 | 5,779 | 3,827 | 210 |
2005** | 84,672 | 62,086 | 35.3 | 22,586 | 26.7 | 10.8 | 13,430 | 172 | 5,060 | 3,649 | 281 |
2006 | 90,024 | 68,355 | 49.0 | 21,670 | 24.1 | 11.5 | 11,313 | 153 | 5,900 | 4,073 | 231 |
2007 | 90,374 | 66,779 | 45.5 | 23,595 | 26.1 | 10.6 | 13,991 | 188 | 5,719 | 3,419 | 274 |
2008 | 87,247 | 60,277 | 31.4 | 26,970 | 30.9 | 11.5 | 16,909 | 261 | 5,250 | 4,346 | 280 |
2009* | 80,795 | 59,895 | 30.5% | 20,900 | 25.9% | 10.3% | 12,564 | 276 | 8,100*** | ||
* = preliminary information, ** = decline based on the forest industry strike, RE = Renewable energy, Black L=Black liquor ***=no detailed info |
The renewable energy of primary energy was 24.0% (2005) and 24.1% (2004). Total primary energy supply was 392,022 (2005) and 418,672 GWh (2004). The primary energy includes in addition to the energy consumption also e.g. the heating up of the Baltic Sea by the nuclear power plant waste heat.
Renewable energy of energy consumption GWh[34][37][38] | ||||||||||
---|---|---|---|---|---|---|---|---|---|---|
Year | Energy | Non-RE growth % |
RE | RE % | Wood | Water | Wind | Other* | ||
1990 | 317,321 | 0% | 57,895 | 18.2 | 46,450 | 10,752 | 0 | 693 | ||
1991 | 312,743 | -1.8% | 57,889 | 18.5 | 44,064 | 13,066 | 1 | 758 | ||
1992 | 309,616 | -4.0% | 60,491 | 19.5 | 44,768 | 14,957 | 2 | 764 | ||
1993 | 319,025 | -1.8% | 64,275 | 20.1 | 50,132 | 13,339 | 4 | 800 | ||
1994 | 340,946 | 5.0% | 68,515 | 20.1 | 56,044 | 11,662 | 7 | 802 | ||
1995 | 334,853 | 1.6% | 71,397 | 21.3 | 57,650 | 12,788 | 11 | 948 | ||
1996 | 349,424 | 7.0% | 71,847 | 20.6 | 59,107 | 11,704 | 11 | 1,025 | ||
1997 | 359,309 | 8.1% | 78,790 | 21.9 | 65,877 | 11,795 | 17 | 1,101 | ||
1998 | 364,033 | 7.6% | 84,941 | 23.3 | 68,788 | 14,777 | 23 | 1,353 | ||
1999 | 372,798 | 9.0% | 89,947 | 24.1 | 75,781 | 12,547 | 49 | 1,570 | ||
2000 | 367,600 | 6.8% | 90,636 | 24.7 | 74,364 | 14,453 | 77 | 1,742 | ||
2001 | 380,769 | 12.9% | 87,762 | 23.0 | 72,573 | 13,018 | 70 | 2,101 | ||
2002 | 392,116 | 16.0% | 91,209 | 23.3 | 78,275 | 10,623 | 63 | 2,248 | ||
2003 | 413,478 | 23.8% | 92,200 | 22.3 | 79,903 | 9,455 | 92 | 2,750 | ||
2004 | 412,040 | 19.5% | 102,113 | 24.8 | 83,961 | 14,865 | 120 | 3,167 | ||
2005** | 381,568 | 10.3% | 95,434 | 25.0 | 78,036 | 13,428 | 168 | 3,802 | ||
2006 | 417,021 | 21.0% | 103,213 | 24.8 | 87,534 | 11,313 | 153 | 4,212 | ||
2007 | 410,273 | 18.4% | 103,063 | 25.1 | 83,929 | 13,991 | 188 | 4,936 | ||
2008 | 392,776 | 9.4% | 109,015 | 27.8 | 83,929 | 16,909 | 261 | 7,916 | ||
2009* | 369,837 | 5.9% | 95,116 | 25.7 | 72,722 | 12,564 | 276 | 9,554 | ||
RE = Renewable Energy, Non-RE = Non-renewable energy + import, Wood = Black liquor, industry and small scale wood fuels, * = Preliminary information 2009, ** = decline based on long forest industry strike in 2005 Other RE 2006 (GWh): Heat pumps – electricity 2,397, Recycled fuel 1,062, Biogas 424, Other Bioenergy 252, Biofuel 10, Solar power 11 | ||||||||||
In the table is the contribution of RE to electricity production for the EU-25 by 2020.
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