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Wind power is a major source of electricity in Germany. Over a fourth of Germany's total electricity in 2024 was generated throughwind power, up from 6.2% in 2010 and 1.6% in 2000.[2]In 2024, wind power produced 136.9TWh, of which 111.9 TWh onshore (25.9% of electricity consumption)[3] and 26 TWh offshore.[4]At the end of 2024, the total installed wind power capacity was 72.75gigawatts (GW): 63.55 GW onshore (28,717 wind turbines)[5] and 9.2 GW (1,639 wind turbines) offshore.[6]
Wind power is a growing industry in the country, with a number of turbine manufacturers, likeEnercon,Nordex andSenvion.
TheGerman Federal Government has enacted plans to expandoffshore wind energy, with targets of 30 gigawatts by 2030, increasing to 70 gigawatts by 2045. This move is part of a strategy to enhance the country'srenewable energy portfolio and reduce dependence on energy imports.[7] To achieve these goals, the government is implementing measures to streamline planning and approval processes for wind energy projects.[8]In 2024, the construction of 2,405 new wind turbines (14.056 GW) has been approved, a new record.[3][9]
TheUnited Kingdom has the best potential wind resources in Europe; Germany has far less. Nevertheless in the late 20th century Germany built the largest wind power capacity worldwide. Volkmar Lauber explains this achievement in terms of seven advantages inside Germany:[10]
Since 1995, onshore wind energy has been an important and major industry in Germany.[citation needed] In 1995, the gross production of onshore wind power was 1,530 GWh. By 2019, gross production from onshore wind power was over 101,000 GWh, allowing Germany to power about a fifth of the country from wind.[11]Larger onshore installations are in the works, which could possibly see a larger percentage of wind energy powering Germany.[citation needed] Germany is also notable for having some major wind turbine manufacturers based there, such asEnercon inAurich,Senvion inHamburg, andNordex inRostock.
Offshore wind energy also has great potential in Germany.[12] Wind speed at sea is 70 to 100% higher than onshore and much more constant. As of 2007, a new generation of 5 MW or larger wind turbines which are capable of making full use of the potential of wind power at sea had been developed. This made it possible to operate offshore wind farms in a cost-effective way.[13]
On 15 July 2009, the first offshore German windturbine completed construction. This turbine is the first of a total of 12 wind turbines for thealpha ventus offshore wind farm in the North Sea.[14]
Following the2011 Japanese nuclear accidents, Germany's federal government began work on a new plan for increasingrenewable energy commercialization, with a particular focus onoffshore wind farms.[15] Under the plan, large wind turbines were to be erected far away from the coastlines, where the wind blows more consistently than it does on land, and where the enormous turbines won't bother the inhabitants. The plan aimed to decrease Germany's dependence on energy derived from coal and nuclear power plants.[16]The German government wanted to see 7.6 GW installed by 2020 and as much as 26 GW by 2030.[17]
A major challenge was the lack of sufficient network capacities for transmitting the power generated in the North Sea to the large industrial consumers in southern Germany.[18]
In 2014 410 turbines with 1747 megawatts were added to Germany's offshore windparks. Due to not yet finished grid-connections, only turbines with combined 528.9 megawatts were added to the grid feed at the end of 2014. Despite this, the gigawatt offshore windpower barrier was reportedly breached by Germany around the end of 2014[19] During 2015 offshore windpower was tripled to over 3 gigawatts capacity, signalling the growing importance of this sector.[20]
At the end of 2019, Germany had installed 1,469 offshore wind turbines with a total capacity of 7.52 GW. Capacity in the North Sea reached 6.44 GW, capacity in the Baltic Sea reached 1.08 GW. In total, 25.8 TWh of power were produced in German offshore wind parks in 2019.[21]
TheGerman Federal Government, alongside the state ofLower Saxony and private sector, has pledged €300 million to finance a 30-hectare expansion of theCuxhaven offshore terminal, with construction mandated to start before planning permission expires in February 2025. This expansion is part of a broader initiative to boost Germany's offshore wind capacity from 8.3 GW to 30 GW by 2030 and 70 GW by 2045, requiring an estimated 200 hectares of additional port area by the end of the 2020s to support new wind farm constructions.[22][23][24]
Since 2011, Germany's federal governments have been working on a new plan for increasingrenewable energy commercialization,[25] with a particular focus onoffshore wind farms.[16]
In 2016, theThird Merkel cabinet decided to replace feed-in tariffs with auctions from 2017, citing the mature nature of the windpower market being best served in this way.[26] These auctions have resulted in some future offshore wind farms to be operated at market prices and receive no subsidy.[27]
As part of measures to increase wind power installations and usage, theScholz cabinet adopted a law requiring Germany to set aside 2% of its total land area by 2032 for wind energy use.[28]
The 2010 "Energiewende" policy has been embraced by the German federal government and has resulted in a huge expansion of renewables, particularly wind power.Germany's share of renewables has increased from around 5% in 1999 to 17% in 2010, reaching close to the OECD average of 18% usage of renewables.[29] Producers were guaranteed a fixed feed-in tariff for 20 years, guaranteeing a fixed income. Energy co-operatives have been created, and efforts were made to decentralize control and profits. The large energy companies had a disproportionately small share of the renewables market. Nuclear power plantswere closed starting in 2011 after Fukushima, and 9 reactors closed2015 — April 2023.
 | This article needs to beupdated. Please help update this article to reflect recent events or newly available information.(August 2025) |
The reduction of reliance on nuclear plants temporarily had the consequence of increased reliance on fossil fuels. 2023 was the first year in which Germany imported more electricity than it exported.[30][31] One factor that has inhibited efficient employment of new renewable energy has been the lack of an accompanying investment in power infrastructure (SüdLink) to bring the power to market.[29][32] The transmission constraint sometimes caused Germany to payDanish wind power to stop producing; in October/November 2015 this amounted to 96 GWh costing 1.8 million euros.[33]
TheGerman states have varying attitudes to the construction of new power lines. Industry has had their rates frozen and so the increased costs of the Energiewende have been passed on to consumers, who have had rising electricity bills. Germans in 2013 had some of the highest electricity costs in Europe.[34]
In Germany, hundreds of thousands of people have invested in citizens' wind farms across the country and thousands of small and medium-sized enterprises are running successful businesses in a new sector that in 2015 employed 142,900 people and generated 12.3 percent of Germany's electricity in 2016.[35]
However, more recently, there has been increasing local resistance to the expansion of wind power in Germany, due to its impact on the landscape, incidents where patches of forest where removed to build wind turbines, the emission of low frequency noise,[36][37] and the negative impact on wildlife, such as birds of prey and bats.[38][39]
Repowering, the replacement of first-generation wind turbines with modern multi-megawatt machines, is occurring in Germany. Modern turbines make better use of available wind energy and so more wind power can come from the same area of land. Modern turbines also offer much better grid integration since they use a connection method similar to conventional power plants.[40][41]
Installed wind power capacity and generation in recent years is shown in the tables below:
| Year | 1990 | 1991 | 1992 | 1993 | 1994 | 1995 | 1996 | 1997 | 1998 | 1999 |
|---|---|---|---|---|---|---|---|---|---|---|
| Installed capacity (MW) | 55 | 106 | 174 | 326 | 618 | 1,121 | 1,549 | 2,089 | 2,877 | 4,435 |
| Net generation (GW·h) | 71 | 100 | 275 | 600 | 909 | 1,500 | 2,032 | 2,966 | 4,489 | 5,528 |
| Capacity factor | 14.74% | 10.77% | 17.99% | 21.01% | 16.79% | 15.28% | 14.93% | 16.21% | 17.81% | 14.23% |
| Year | 2000 | 2001 | 2002 | 2003 | 2004 | 2005 | 2006 | 2007 | 2008 | 2009 |
| Installed capacity (MW) | 6,097 | 8,738 | 11,976 | 14,381 | 16,419 | 18,248 | 20,474 | 22,116 | 22,794 | 25,732 |
| Net generation (GW·h) | 9,513 | 10,509 | 15,786 | 18,713 | 25,509 | 27,229 | 30,710 | 39,713 | 40,574 | 38,648 |
| Capacity factor | 17.76% | 13.73% | 15.05% | 14.85% | 17.69% | 17.03% | 17.12% | 20.50% | 20.26% | 17.15% |
| Year | 2010 | 2011 | 2012 | 2013 | 2014 | 2015 | 2016 | 2017 | 2018 | 2019 |
| Installed capacity (MW) | 26,903 | 28,712 | 30,979 | 33,477 | 38,614 | 44,541 | 49,534 | 55,550 | 59,420 | 61,357 |
| Net generation (GW·h) | 37,793 | 48,882 | 50,671 | 51,708 | 57,357 | 79,084 | 78,416 | 103,707 | 107,889 | 123,545 |
| Capacity factor | 16.04% | 19.43% | 18.62% | 17.63% | 16.96% | 20.27% | 18.02% | 21.31% | 20.73% | 22.99% |
| Year | 2020 | 2021 | ||||||||
| Installed capacity (MW) | 62,708 | 63,865 | ||||||||
| Net generation (GW·h) | 129,644 | 111,734 | ||||||||
| Capacity factor | 23.54% | 19.97% | ||||||||
| Year | 2009 | 2010 | 2011 | 2012 | 2013 | 2014 | 2015 | 2016 | 2017 | 2018 | 2019 | 2020 | 2021 |
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Installed capacity (MW) | 30 | 80 | 188 | 268 | 508 | 994 | 3,283 | 4,152 | 5,406 | 6,393 | 7,555 | 7,774 | 7,774 |
| Generation (GW·h) | 38 | 174 | 568 | 722 | 905 | 1,449 | 8,162 | 12,092 | 17,414 | 19,179 | 24,379 | 26,903 | 24,014 |
| Generation in the North Sea (in TWh) | 20.2 | 22.8 | 18.5 | ||||||||||
| Generation in the Baltic Sea (in TWh) | 4.1 | 4.2 | 3.5 | ||||||||||
| % of wind gen. | 0.1 | 0.5 | 1.2 | 1.4 | 1.8 | 2.6 | 10.5 | 16.0 | 16.8 | 14.99 | 19.2 | 20 | 21.1 |
| Capacity factor | 12.39% | 24.83% | 34.49% | 30.67% | 20.34% | 16.64% | 28.38% | 33.15% | 36.77% | 34.25% | 36.84% | 39.40% | 35.26% |
| This section needs to beupdated. Please help update this article to reflect recent events or newly available information.(May 2018) |
| State | No. turbines | Installed capacity [MW] | Watts per capita | % share in electrical consumption [2011] |
|---|---|---|---|---|
 Saxony-Anhalt | 2,830 | 5,309 | 2,447 | 48.11 |
 Brandenburg | 3,984 | 8,067 | 3,178 | 47.65 |
 Schleswig-Holstein | 3,067 | 7,215 | 2,469 | 46.46 |
 Mecklenburg-Vorpommern | 1,837 | 3,556 | 2,207 | 46.09 |
 Lower Saxony | 6,101 | 11,785 | 1,468 | 24.95 |
 Thuringia | 850 | 1,733 | 821 | 12.0 |
 Rhineland-Palatinate | 1,758 | 3,862 | 940 | 9.4 |
 Saxony | 871 | 1,273 | 314 | 8.0 |
 Bremen | 87 | 201 | 297 | 4.7 |
 North Rhine-Westphalia | 3,573 | 6,548 | 365 | 3.9 |
 Hesse | 1,139 | 2,337 | 371 | 2.8 |
 Saarland | 213 | 520 | 529 | 2.5 |
 Bavaria | 1,132 | 2,575 | 195 | 1.3 |
 Baden-Württemberg | 772 | 1,729 | 155 | 0.9 |
 Hamburg | 67 | 122 | 65 | 0.7 |
 Berlin | 6 | 17 | 4 | 0.0 |
| Onshore total | 28,287 | 56,848 | ||
| offshoreNorth Sea | 1,269 | 6,698 | ||
| offshoreBaltic Sea | 232 | 1,096 | ||
| Offshore total | 1,501 | 7,794 | ||
| Germany Total | 29,788 | 64,642 | 776 | 17.6 |
