The Energiewende (German for 'energy turnaround') (pronounced [ʔenɐˈɡiːˌvɛndə] ) is the ongoing energy transition by Germany. The new system intends to rely heavily on renewable energy (particularly wind, photovoltaics, and hydroelectricity), energy efficiency, and energy demand management.
Legislative support for the Energiewende was passed in late 2010 and included greenhouse gas (GHG) reductions of 80–95% by 2050 (relative to 1990) and a renewable energy target of 60% by 2050. Germany had made progress on its GHG emissions reduction target before the introduction of the program, achieving a 27% decrease between 1990 and 2014. The Country would need to maintain an average GHG emissions abatement rate of 3.5% per year to reach its Energiewende goal, equal to the maximum historical value. Germany's energy mix has a high CO2 intensity due a significant coal and fossil gas usage.
Germany phased out nuclear power in 2023 as part of the Energiewende, and plans to retire existing coal power plants possibly by 2030, and latest by 2038. The early retirement of the Country's nuclear reactors was supported by the general public, the plan was controversial between energy experts, fearing that it could have a negative impact on Germany's goals to reduce greenhouse gas emissions.
Etymology
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The term Energiewende is regularly used in English language publications without being translated (a loanword).
The term Energiewende was first contained in the title of a 1980 publication by Öko-Institut, calling for the complete abandonment of nuclear and petroleum energy. The most groundbreaking claim was that economic growth was possible without increased energy consumption. On 16 February 1980, the German Federal Ministry of the Environment hosted a symposium in Berlin called Energiewende: Atomausstieg und Klimaschutz (Energy Transition: Nuclear Phase-Out and Climate Protection). The Öko-Institut was funded by environmental and religious organizations, and the importance of religious and conservative figures like Wolf von Fabeck [de] and Peter Ahmels were crucial. In the following decades, the term Energiewende expanded in scope; in its present form, it dates back to 2002.
Energiewende designated a significant change in energy policy. The term encompassed a reorientation of policy from demand to supply and a shift from centralized to distributed generation (for example, producing heat and power in small co-generation units), which replace overproduction and avoidable energy consumption with energy-saving measures and increased efficiency.
In a broader sense, the transition also entailed a democratization of energy. In the traditional energy industry, a few companies with large centralized power stations were perceived as dominating the market as an oligopoly and consequently amassing a worrisome level of both economic and political power. Renewable energies can be established in a decentralized manner. Public wind farms and solar parks can involve many citizens directly in energy production. Photovoltaic systems can be set up by individuals. Municipal utilities can also benefit citizens financially, while the conventional energy industry profits from a relatively small number of shareholders. The decentralized structure of renewable energies, enables the creation of value locally and minimizes capital outflows from a region. Renewable energy sources, play an important role in municipal energy policy, and local governments promote the sources.
Status
The policy document outlining the Energiewende was published by the German government in September 2010, six months before the Fukushima nuclear accident. Legislative support was passed in September 2010. On 6 June 2011, following Fukushima, the government removed the use of nuclear power as a bridging technology as part of their policy. The program was later described as "Germany's vendetta against nuclear" and attributed to the influence of ideologically anti-nuclear green movements in politics. In 2014, then-Federal Minister for Economic Affairs and Energy Sigmar Gabriel lobbied Swedish company Vattenfall to continue investments in brown coal mines in Germany, explaining that "we cannot simultaneously quit nuclear energy and coal-based power generation.". A similar statement by Gabriel was recalled by James Hansen in his 2009 book "Storms of My Grandchildren" — Gabriel argued that "coal use was essential because Germany was going to phase out nuclear power. Period. It was a political decision, and it was non-negotiable".
In 2011, the Ethical Committee on Secure Energy Supply was tasked with assessing the feasibility of the nuclear phase-out and transition to renewable energy, and it concluded:
The Ethics Committee is firmly convinced that the phase-out of nuclear energy can be completed within a decade using the energy transition measures presented here.
— Deutschlands Energiewende. Ein Gemeinschaftswerk für die Zukunft, Ethik‐Kommission Sichere Energieversorgung
In 2019, Germany's Federal Court of Auditors determined the program had cost €160 billion over the last 5 years and criticized the expenses for being "in extreme disproportion to the results." Despite widespread initial support, the program is perceived as "expensive, chaotic, and unfair", and a "massive failure" as of 2019.
Russian fossil gas was perceived as a "safe, cheap, and temporary" fuel to replace nuclear power in the initial phase of Energiewende as part of the German policy of integrating Russia with the European Union through mutually beneficial trade relations. German dependency on Russian gas imports was presented as "mutual dependency."
See also: Ostpolitik and Wandel durch HandelInitial phase 2013–2016
After the 2013 federal elections, the new Christian Democratic Union of Germany (CDU) /Christian Social Union in Bavaria (CSU) and Social Democratic Party of Germany (SPD) coalition government continued the Energiewende, with minor modification of its goals in the coalition agreement. The coalition government introduced an intermediate target of a 55–60% share of renewable energy in gross electricity consumption in 2035. The targets were described as "ambitious". The Berlin-based policy institute Agora Energiewende noted that "while the German approach is not unique worldwide, the speed and scope of the Energiewende are exceptional". A characteristic of the Energiewende compared to other planned energy transitions was the expectation that the transition is driven by citizens and not large energy utilities. Germany's switch to renewable energy was described as "democratization of the energy supply". The Energiewende also sought a greater transparency in relation to national energy policy formation.
As of 2013, Germany was spending €1.5 billion per year on energy research to solve the technical and social issues raised by the transition, which are provided by the individual federal states, universities, and the government, which provided €400 million per year. The Government's contribution was increased to €800 million in 2017.
Important aspects included (as of November 2016):
Target | 2016 | 2020 | 2030 | 2040 | 2050 | |
---|---|---|---|---|---|---|
Greenhouse gas emissions | ||||||
Greenhouse gas emissions (the base year 1990) | −27.3% | −40% | −55% | −70% | −80 to −95% | |
Renewable energy | ||||||
Share of gross final energy consumption | 14.8% | 18% | 30% | 45% | 60% | |
Share of gross electricity consumption | 31.6% | 35% | 50% | 65% | 80% | |
Share of heat consumption | 13.2% | 14% | ||||
Share in the transport sector | 6.9% | 10% | 14% | |||
Efficiency and consumption | ||||||
Primary energy consumption (the base year 2008) | −6.5% | −20% | −50% | |||
Final energy productivity (2008–2050) | 1.1% per year (2008–2016) |
2.1% per year (2008–2050) | ||||
Gross electricity consumption (the base year 2008) | −3.6% | −10% | −25% | |||
Primary energy consumption in buildings (the base year 2008) | −18.3% | −80% | ||||
Heat consumption in buildings (base year 2008) | −6.3% | −20% | ||||
Final energy consumption in transport (base year 2005) | 4.2% | −10% | −40% |
In addition, there was an associated research and development drive. A chart showing German energy legislation in 2016 is available.
The targets went beyond European Union legislation and the national policies of other European states. The policy objectives have been embraced by the German Federal Government and has resulted in an expansion of renewable energy, particularly wind power. Germany's share of renewables has increased from around 5% in 1999 to 22.9% in 2012, surpassing the OECD average of 18% usage of renewables. Producers have been 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. Poor investment designs have caused bankruptcies and low returns, and unrealistic promises have been shown to be far from reality.
See also: DesertecNuclear power plants were closed, and the existing nine plants were scheduled to close earlier than planned, in 2022.
A factor that inhibited efficient employment of new renewable energy has been the lack of an accompanying investment in power infrastructure to bring the power to market. It is believed 8,300 km (5,200 mi) of power lines must be built or upgraded. In 2010 legislation has been passed seeking construction and upgrade of 7,700 km (4,800 mi) of new grid lines, 950 km (590 mi) have been built by 2019 — and in 2017, 30 km (19 mi) has been built.
The German States have varying attitudes to the construction of new power lines. Industry has had their rates frozen and the increased costs of the Energiewende had been passed on to consumers, who have had rising electricity bills. Germans in 2013 had the highest electricity prices (including taxes) in Europe. In comparison, its neighbours (Poland, Sweden, Denmark and nuclear-reliant France) have some of the lowest costs (excluding taxes) in the EU.
On 1 August 2014, a revised Renewable Energy Sources Act entered into force. Deployment corridors stipulated the extent to renewable energy to be expanded in the future and the funding rates (feed-in tariffs) will no longer be fixed by the government, but will be determined by auction.
Market redesign was perceived as a key part of the Energiewende. The German electricity market needed to be reworked to suit. Wind and solar power cannot be principally refinanced under the current marginal cost based market. Carbon pricing is also central to the Energiewende, and the European Union Emissions Trading Scheme (EU ETS) needs to be reformed to create a genuine scarcity of certificates. The German Federal Government is calling for a reform. Most of the computer scenarios used to analyse the Energiewende rely on a substantial carbon price to drive the transition to low-carbon technologies.
Coal-fired generation needs to be retired as part of the Energiewende. Some argue for an explicit negotiated phase-out of coal plants, along the lines of the well-publicized nuclear phase-out, but as German minister of economy noted, "we cannot shut down both our nuclear and coal-fired power plants". Coal comprised 42% of electricity generation in 2015. A phase-out of fossil fuels together with a shift to 100% renewable energy is required by about 2040.
The Energiewende is made up of various building blocks and assumptions. Electricity storage was hoped to become a useful technology in the future. As of 2019, a number of potential storage projects (power-to-gas, hydrogen storage and others) are still in prototype phase with losses up to 40% of the stored energy in the existing small scale installations.
Energy efficiency plays a key but under-recognised role. Energy efficiency is one of Germany's targets. Integration with national electricity networks can offer benefits. Systems with high shares of renewables can use geographical diversity to offset intermittency.
Germany invested €1.5 billion in energy research in 2013. The German Federal Government spent €820 million supporting projects ranging from basic research to applications. The federal government also foresees an export role for German expertise in the area.
The social and political dimensions of the Energiewende have been subject to study. Sebastian Strunz argues that the underlying technological, political and economic structures will need to change radically — a process He calls "regime shift". Eva Schmid, Brigitte Knopf, and Anna Pechan analyze the actors and institutions that will be decisive in the Energiewende and how latency in the national electricity infrastructure may restrict progress.
On 3 December 2014, the German Federal Government released its National Action Plan on Energy Efficiency (NAPE) in order to improve the uptake of energy efficiency. The areas covered are the energy efficiency of buildings, energy conservation for companies, consumer energy efficiency, and transport energy efficiency. German industry is expected to make a sizeable contribution.
An official Federal Government report on progress under the Energiewende, notes:
- energy consumption fell by 4.7% in 2014 (from 2013) and at 13132 petajoules reached its lowest level since 1990
- renewable generation is the number-one source of electricity
- energy efficiency increased by an average annual 1.6% between 2008 and 2014
- final energy consumption in the transport sector was 1.7% higher in 2014 than in 2005
- for the first time in more than ten years, electricity prices for household customers fell at the beginning of 2015
A commentary on the progress report expands on many of the issues raised.
Slowdown from 2016
Slow progress on transmission network reinforcement had led to a deferment of new windfarms in northern Germany. The German cabinet approved costly underground cabling in October 2015 in a bid to dispel local resistance against above-ground pylons and to speed up the expansion process.
Analysis by Agora Energiewende in late-2016 suggests that Germany will probably miss several of its key Energiewende targets, despite recent reforms to the Renewable Energy Sources Act and the wholesale electricity market. The goal to cut emissions by 40% by 2020 "will most likely be missed ... if no further measures are taken" and the 55–60% share of renewable energy in gross electricity consumption by 2035 is "unachievable" with the current plans for renewables expansion. In November 2016, Agora Energiewende reported on the impact of the EEG (2017) and several other related new laws. It concludes that the new legislation will bring "fundamental changes" for large sections of the energy industry, but have limited effect on the economy and on consumers.
The 2016 Climate Action Plan for Germany, adopted on 14 November 2016, introduced sector targets for greenhouse gas (GHG) emissions. The goal for the energy sector is shown in the table. The plan states that the energy supply must be "almost completely decarbonised" by 2050, with renewable energy as its main source. For the electricity sector, "in the long-term, electricity generation must be based almost entirely on renewable energies" and "the share of wind and solar power in total electricity production will rise significantly". Notwithstanding, during the transition, "less carbon-intensive natural gas power plants and the existing most modern coal power plants play an important role as interim technologies".
Sector | 1990 | 2014 | 2030 | Reduction (2030 relative 1990) |
---|---|---|---|---|
Energy | 466 | 358 | 175–183 | 61–62% |
Buildings | 209 | 119 | 70–72 | 66–67% |
Transport | 163 | 160 | 95–98 | 40–42% |
Industry | 283 | 181 | 140–143 | 49–51% |
Agriculture | 88 | 72 | 58–61 | 31–34% |
Other | 39 | 12 | 5 | 87% |
Total | 1248 | 902 | 543–562 | 55–56% |
|
The fifth monitoring report on the Energiewende for 2015 was published in December 2016. The expert commission which wrote the report warns that Germany will probably miss its 2020 climate targets and believes that this could threaten the credibility of the entire endeavour. The commission puts forward a number of measures to address the slowdown, including a flat national CO2 price imposed across all sectors, a greater focus on transport, and full market exposure for renewable generation. Regarding the carbon price, the commission thinks that a reformed EU ETS would be better, but that achieving agreement across Europe is unlikely.
After 2017
Since 2017, it had become clear that the Energiewende was not progressing at the anticipated speed, with the Country's climate policy regarded as "lackluster" and the energy transition "stalling." High electricity prices, growing resistance against the use of wind turbines over their environmental and potential health impacts, and regulatory hurdles, have been identified as causes for the slowdown. As of 2017 Germany imported more than half of its energy.
A 2018 European Commission case study report on the Energiewende noted 27% decrease in CO2 emissions against the 1990 levels with a slight increase over the few preceding years and concluded achieving of the intended 40% reduction target by 2020 in unfeasible, primarily due to the "simultaneous nuclear phase-out and increased energy consumption". 50% increase of electricity prices was observed (compared to base 2007 prices). Germany's energy sector remains the largest single source of CO2 emissions, contributing over 40%.
In 2018 the slow-down of deployment of new renewable energy was partially attributed to high demand for land, which has been highlighted as a potential "downside" by a WWF report.
See also: Surface power densityIn March 2019, Chancellor Merkel formed a "climate cabinet" to find a consensus on new emissions reduction measures to meet 2030 targets. The result was the Climate Action Program 2030, which Berlin adopted on 9 October 2019. The Program contains plans for a carbon pricing system for the heating and transportation sectors, which are not covered by the EU ETS. It includes tax and other incentives to encourage energy-efficient building renovations, higher EV subsidies, and more public transport investments. The IEA report concludes that "he package represents a clear step in the right direction towards Germany meeting its 2030 targets." The German Coal Commission, composed of 28 industrial, environmental, and regional organizations, voted on the coal phase-out date. 27 members voted in favor of the 2038 coal phase-out date, with only one regional organization from Lusatia voting against, and Greenpeace voting in favor and later releasing a non-binding "dissenting opinion".
As result of phasing out nuclear power and, in long term, coal, Germany declared increased reliance on fossil gas.
We will have phased out nuclear energy by 2022. We have a very difficult problem, namely that almost the only sources of energy that will be able to provide baseload power are coal and lignite. Naturally, we cannot do without baseload energy. Natural gas will therefore play a greater role for another few decades. I believe we would be well advised to admit that if we phase out coal and nuclear energy then we have to be honest and tell people that we'll need more natural gas.
— Angela Merkel, Speech at 49th World Economic Forum Annual Meeting in Davos on 23 January 2019
A similar statement was voiced by SPD MP Udo Bullmann who explained that Germany has to stick with fossil fuels as it's trying to replace both coal and nuclear "at the same time", while countries that rely on nuclear power have "easier task replacing fossil fuels". In 2020 Agora Energiewende also declared a number of new fossil gas plants will be also required to "guarantee supply security as Germany relies more and more on intermittent renewable electricity". In January 2019, Germany's Economy Minister Peter Altmaier didn't want to import "cheap nuclear power" from other countries to compensate for planned phase-out of coal. In 2021 Green MEP Sven Giegold admitted that Germany may require new fossil gas power plants in order to "stabilise the more fluctuating power supply of renewables".
The 2020 climate goals were successful in the following areas:
- closure of nuclear plants
- increasing renewable energy share
- reducing greenhouse gas emissions
The following climate goals failed:
- increasing renewable energy share in the transport sector
- reducing primary energy consumption
- final energy productivity.
In 2020, a number of previously shut down fossil gas plants (Irsching units 4 and 5) were restarted due to "heavy fluctuations of level of power generated from the wind and sun" and a new fossil gas power plant was announced by RWE near the former Biblis nuclear power plant shut down in 2017. The project is declared as part of "decarbonization plan" where renewable energy capacity is accompanied by fossil gas plants to cover for intermittency. In 2020, a new coal power plant unit, Datteln 4, was also connected to the grid. A new fossil gas power plant will be also opened from 2023 in Leipheim, Bavaria to compensate for loss of power caused by "nuclear exit" in the Region. In 2021, the planned decommissioning of Heyden 4 coal power plant was cancelled and the plant remains online to compensate for shutdown of the Grohnde nuclear power station. In 2022, another coal power plant was restarted in Schongau, Bavaria for the same reasons.
In June 2021, professor André Thess [de] from Stuttgart university published an open letter accusing Klaus Töpfer and Matthias Kleiner, the authors of the 2011 Ethical Committee for Secure Energy Supply report that served as the scientific background of the "nuclear exit" decision, of disregarding the basic rules of scientific independence. The analysis promised that phase-out of nuclear energy and full transition to renewable energy "can be completed within a decade". Thess highlighted that the authors lacked the expertise necessary to properly understand and "balance between the risk of more rapid climate change without nuclear energy and the risk of slower climate change with nuclear energy".
High average amounts of wind in 2019 and 2020 were presented in Germany as a success of renewable energy, but when the amount of wind was low for the first half of 2021, use of coal rose by 21% as compared to the previous years. In the first half of 2021 coal, gas, and nuclear power delivered 56% of overall electricity in Germany, with proportionally higher CO2 intensity due to high inputs from coal and fossil gas. According to another analysis by Oekomoderne, in 2021, Germany produced nearly 260 TWh of electricity from coal in the first half of 2021, making it the single largest source of energy in that period — as it used "one billion tons" of coal.
The situation once again raised questions about the future of weather-dependent electricity system that is dependent on fossil energy for stability and its contradiction with the initial objectives of decarbonization.
Projections Report published in 2021 predicted that Germany will miss its 2030 target by 16% (49% reduction vs 65% planned) and the 2040 target by 21% (67% vs 88% planned). Reduction of emissions in other sectors of the economy is also expected to miss the original targets.
In October 2021, over 20 climate scientists and activists signed an open letter to the German Government to reconsider the nuclear exit as it will lead to emissions of an extra 60 million tons of CO2 each year and hinder decarbonization efforts even further.
The new coalition formed after the 2021 elections proposed earlier phase-out of coal and internal combustion cars by 2035, 65% energy generated from renewables by 2030 and 80% by 2040. In addition, 2% of land surface is to be set aside for on-shore wind power, and off-shore wind capacity is to be increased to 75 GW. Fossil gas role was reinforced as "indispensable" transition fuel with low-carbon nuclear power imported from France to ensure stability of supplies.
By end of 2021, the single largest source of electricity in Germany was coal (9.5% hard and 20.2% brown), increase of 20% compared to 2020 due to significant drop in wind (−14.5%) and solar (−5%) power output in that year. Solar power only produced 9.9% electricity, while nuclear power produced 13% as it was going through the process of decommissioning.
In 2022, Agora Energiewende warned that Germany has missed its 2020 emission targets and is likely going to miss the 2030 targets, and increase of total emissions after 2022 is likely. Previously celebrated 2020 record low emissions were described as one-off effect of favorable weather and lower demand due to COVID-19 pandemics. Nuclear phase-out, skyrocketing gas prices, and low wind and solar output resulting in increased reliance on coal were also attributed to the increase in emissions.
In January 2022 the new coalition government reiterated its opposition to the inclusion of nuclear power in the EU sustainable taxonomy, but also requested that fossil gas is instead included as a "transitional" fuel and carbon intensity thresholds for gas are relaxed. As the subsidies for gas were upheld, a number of new fossil gas plants plan to benefit from the subsidies, while expecting increased profits thanks to "rising wholesale electricity prices" as result of "the last nuclear power plants to be removed from the grid" at the same time.
In 2023, Germany achieved its lowest greenhouse gas emissions since the 1950s with a 20% reduction, largely impacted by a decline in industrial production due to economic factors like the Ukraine war and high energy prices. The Berlin-based think-tank Agora Energiewende attributed approximately half of the reduction to decreased coal-fired power generation, while only 15% resulted from technological improvements such as enhanced renewable energy utilization. Despite these gains, with over 50% of Germany's electricity now derived from renewable energy, concerns persist about the industrial sector's competitiveness and sustainability, as emission levels in construction and transport have not changed, putting Germany at risk of missing its EU emission targets.
Post-2022
Following the 2022 Russian invasion of Ukraine, Germany announced they would re-open 10 GW of coal power to allegedly "conserve natural gas" following the shortage in Europe. This led to a subsequent criticism of Energiewende's strategy, and how this impacted different countries in Europe. Michael Kretschmer (CDU) declared the Energiewende to be a failure, highlighting that renewable generation is insufficient and baseload capabilities have reached its limits. He called for nuclear power phase-out to be cancelled and remaining reactors restarted, until a new feasible strategy is created.
From February 2022, there was a heated debate about pausing the nuclear phase-out and restarting still operational reactors in order to better cope with the energy crisis caused by the Russian invasion of Ukraine. In August 2022, German counter-intelligence started an investigation into two high-ranked officials at German ministry of energy suspected of representing interests of Russia.
In October 2022, Germany ministry of energy approved extension of RWE brown coal open pit mine in Lutzerath, claiming it's "necessary for energy security". In October 2022, the Government also declared the operational nuclear power plants will not be shut down by end of 2022, but will instead operate until 15 April to help cope with the electricity demand through the winter.
In 2023, the Government declared its plans to remove a key clause from the law that binds all ministries to reduce carbon emissions within their area of responsibility. The binding target will be the overall 2030 emissions reduction target. The largest CO2 emissions source in Germany is its electricity production, and in that sector, emissions have roughly halved from its peak in 2007 until 2023. 2020 already saw a similar decline as 2023, as electricity demand dropped massively due to COVID-19 lockdowns, leading to an annual average CO2 intensity of German electricity production of 364 gCO2/kWh (2023: 380 gCO2/kWh). In 2022, the cut-off from Russian gas lead to a brief restarting of coal power plants, meaning the share of coal in electricity production increased from 24% in 2020 to 32% in 2022, before going down to 27% in 2023.
In 2023 Energy Economics Institute (EWI) warned that around 50 new fossil gas powered plants need to be built to "compensate for the weather-dependent production of wind and solar power" with the overall cost reaching €60 billion. The budget is not secured by the Government nor available from the electricity sales. To move away from coal, in February 2024, the Federal Government agreed to subsidize 10 GW of hydrogen-ready gas plants. In the first years, the plants will use fossil gas and are expected to be switched over to hydrogen between 2035 and 2040. The plants will mainly provide backup capacity in times where solar and wind power are low. As running plants this way is not economically feasible, utilities will be paid for maintaining the baseload capacity.
The last three nuclear power plants in Germany—Emsland, Isar II and Neckarwestheim II—were shut down on 15 April 2023.
In March 2024, Federal Audit Office published a report in which it assessed the policy as not meeting goals on a number of points: the planned 80% share of renewable energy requires dispatchable sources but the assumed 10 GW in fossil gas generation is neither sufficient nor on schedule; extension of electric grid is behind the schedule by 6,000 km (3,700 mi) and 7 years; security of the supply chain is not sufficiently assessed; system costs to ensure 24/7 generation are underestimated and based on "best-case" scenarios; capacity installed in renewables is behind the schedule by 30%, whereas demand is expected to grow by 30% as result of electrification of heating and transport.
In December 2024 Radiant established that with one reactor could be restarted by end of 2025 and further two by 2028, restoring 4 GW of capacity in total.
Criticism
The Energiewende has been criticized for the high costs, the early nuclear phase-out which increased carbon emissions, continuation or increase in use of fossil fuels, risks to power supply stability and the environmental damage of biomass.
German association of local utilities VKU said "the strategy creates significant risks to the stability of power supply in case of 'lengthy periods' of weather unsuitable for wind and solar generation since energy storage in Germany is 'largely non-existent'".
After introduction of the original Renewable Energy Act in 2000, there was a focus on long term costs, while in later years this has shifted to a focus on short term costs and the "financial burden" of the Energiewende while ignoring environmental externalities of fossil fuels. Electricity prices for household customers in Germany have been generally increasing in the last decade. The renewable energy levy to finance green power investment is added to Germans' electricity unit price. The surcharge (22.1% in 2016) pays the state-guaranteed price for renewable energy to producers and is 6.35 cents per kWh in 2016.
A comprehensive study, published in Energy Policy in 2013, reported that Germany's nuclear power phase-out, to be complete by 2022, is contradictory to the goal of the climate portion of the program.
In June 2019, an open letter to "the leadership and people of Germany", written by almost 100 Polish environmentalists and scientist, urged Germany to "reconsider the decision on the final decommissioning of fully functional nuclear power plants" for the benefit of the fight against global warming.
German Economy and Energy Minister Sigmar Gabriel said in 2014 "For a country like Germany with a strong industrial base, exiting nuclear and coal-fired power generation at the same time would not be possible."
As nuclear and coal power plants are being phased out, the Government had begun to promote the use of fossil gas in order to bridge the gap between other fossil fuels and low-carbon energy sources. The move had been criticized by international observers, who argue that fossil fuel gas is "essentially methane, which constitutes at least one-third of global warming and is leaking into the atmosphere all across the gas production and delivery chain." It is also a more potent greenhouse gas than carbon-dioxide. It is also feared that the European Union, but particularly Germany, is making itself overly dependent on Russia for gas supplies via Nord Stream 2, thereby undermining its energy security. In light of the 2022 Russian invasion of Ukraine the Nord Stream 2 project was first postponed indefinitely and ultimately cancelled. The Scholz cabinet has spent considerable efforts since February 2022 to find replacements for Russian fossil gas both in the near and the long term.
Germany's electricity transmission network is currently inadequately developed, therefore lacking the capability of delivering offshore wind energy produced on the Northern coast to industrial regions in the Country's South. The transmission system operators are planning to build an additional 4,000 kilometres (2,500 miles) of transmission lines until 2030.
Slow reduction of CO2 emissions in Germany, had been contrasted with France's successful decarbonization of its energy sector under the Messmer plan (from 1973) and the United Kingdom's carbon tax, which saw a drastic reduction of coal-powered energy from 88% in 1973 to below 1% in 2019.
German federal audit office report published in March 2021 highlighted the very high costs of Energiewende for the household users, where taxes and fees account for 50% of the bills, and the energy price is 43% higher than the EU average. It noted predicted shortage of 4.5 GW between 2022 and 2025 as result of the planned shutdown of nuclear power plants.
A study found that if Germany had postponed the nuclear phase out and phased out coal first, it could have saved 1,100 lives and €3 to €8 billion in social costs per year. The study concludes that policymakers would have to overestimate the risk or cost of a nuclear accident to conclude that the benefits of the phase-out exceed its social costs. An open letter by a number of climate scientists published in 2021 calls against the shut-down of the remaining nuclear reactors in Germany, that would lead to 5% increase in CO2 emissions from the electricity sector. According to a 2024 study, by keeping nuclear power Germany could have achieved 73% drop in CO2 emissions instead of 25% in the study period (2002–2022).
The Renewable Energy Act had a significant impact on businesses and industries and had been met with criticism, resulting in increased costs and slowed-down growth.
During the 2024 presidential debate between the Republican nominee, Donald Trump, and the Democratic nominee, Kamala Harris, Trump criticized Germany's energy transition efforts. But Germany's carbon dioxide levels have fallen nearly 38 percent since 1990. At the same time, it has dramatically increased its use of renewable energy to 57 percent of its electricity consumption in 2024.
Biomass
Biomass made up 7.0% of Germany's power generation mix in 2017. Biomass has the potential to be a carbon-neutral fuel because growing biomass absorbs carbon dioxide from the atmosphere and a portion of the carbon absorbed remains in the ground after harvest. However, using Biomass as a fuel produces air pollution in the form of carbon monoxide, carbon dioxide, NOx (nitrogen oxides), VOCs (volatile organic compounds), particulates and other pollutants, although biomass produces less sulfur dioxide than coal.
Between 2004 and 2011 policies lead to around 7,000 km (2,700 sq mi) new maize-fields for biomass-energy by ploughing-up of at least 2,700 km (1,000 sq mi) of grassland. This released large amounts of climate active gases, loss of biodiversity, and potential of groundwater recharge.
There are attempts to use biogas as partially renewable fuel with Green Planet Energy selling gas containing 10% of biogas, 1% hydrogen and 90% imported fossil gas.
Citizen support and participation
As of 2016, citizen support for the Energiewende remained high, with surveys indicating that about 80–90% of the public are in favor. One reason for the high acceptance was the substantial participation of German citizens in the Energiewende, as private households, land owners, or members of energy cooperatives (Genossenschaft). A 2016 survey showed that roughly one in two Germans would consider investing in community renewable energy projects. Manfred Fischedick, Director of the Wuppertal Institute for Climate, Environment and Energy has commented that "if people participate with their own money, for example in a wind or solar power plant in their area, they will also support ." A 2010 study shows the benefits to municipalities of community ownership of renewable generation in their locality.
Estimates for 2012 suggested that almost half the renewable energy capacity in Germany was owned by citizens through energy cooperatives and private initiatives. Citizens accounted for nearly half of all installed biogas and solar capacity and half of the installed onshore wind capacity.
According to a 2014 survey conducted by TNS Emnid for the German Renewable Energies Agency among 1015 respondents, 94 percent of the Germans supported the enforced expansion of Renewable Energies. More than two-thirds of the interviewees agreed to renewable power plants close to their homes. The share of total energy from renewables was 11% in 2014.
Changes in energy policy, with the Renewable Energy Sources Act in 2014, have jeopardized the efforts of citizens to participate. The share of citizen-owned renewable energy has since dropped to 42.5% as of 2016.
The Renewable Energy Sources Act provides compensation to wind turbine operators for every kilowatt-hour of electricity not produced if wind power surpasses peak grid capacity, while grid operators must splice electricity from renewable sources into the grid in times of low or no demand for it. This can lead to a negative price of electricity, and grid operators may pass associated costs on to customers, estimated to be costing them an extra €4 billion in 2020. This has resulted in greater resistance to certain Energiewende policies, specifically wind power.
By 2019, Germany also saws a significant increase of organized opposition against on-shore wind farms, especially in Bavaria and Baden-Württemberg.
Computer studies
Much of the policy development for the Energiewende is underpinned by computer models, run mostly by universities and research institutes. The models are usually based on scenario analysis and are used to investigate different assumptions regarding the stability, sustainability, cost, efficiency, and public acceptability of various sets of technologies. Some models cover the entire energy sector, while others are confined to electricity generation and consumption. A 2016 book investigates the usefulness and limitations of energy scenarios and energy models within the context of the Energiewende.
A number of computer studies confirm the feasibility of the German electricity system being 100% renewable in 2050. Some investigate the prospect of the entire energy system (all energy carriers) being fully renewable.
2009 WWF study
In 2009 World Wide Fund for Nature (WWF) Germany published a study prepared by the Öko-Institut, Prognos, and Hans-Joachim Ziesing. The study presumes a 95% reduction in greenhouse gases by the year 2050 and covers all sectors. The study shows that the transformation from a high-carbon to a low-carbon economy is possible and affordable. It notes that by committing to this transformation path, Germany could become a model for other countries.
2011 German Advisory Council on the Environment study
A 2011 report from the German Advisory Council on the Environment (SRU) concludes that Germany can attain 100% renewable electricity generation by 2050. The German Aerospace Center (DLR) REMix high-resolution energy model was used for the analysis. A range of scenarios were investigated and a cost-competitive transition with good security of supply is possible.
The authors presume that the transmission network will continue to be reinforced and that cooperation with Norway and Sweden would allow their hydro generation to be used for storage. The transition does not require Germany's nuclear phase-out (Atomausstieg) to be extended nor the construction of coal-fired plants with carbon capture and storage (CCS). Conventional generation assets need not be stranded and an orderly transition should prevail. Stringent energy efficiency and energy saving programs can bring down the future costs of electricity.
2015 Deep Decarbonization Pathways Project study
The Deep Decarbonization Pathways Project (DDPP) aims to demonstrate how countries can transform their energy systems by 2050 in order to achieve a low-carbon economy. The 2015 German country report, produced in association with the Wuppertal Institute, examines the official target of reducing domestic GHG emissions by 80% to 95% by 2050 (compared with 1990). Decarbonization pathways for Germany are illustrated by means of three scenarios with energy-related emission reductions between 1990 and 2050 varying between 80% and more than 90%. The three strategies strongly contribute to GHG emission reduction:
- energy efficiency improvements (in all sectors, especially in buildings)
- increased use of domestic renewables (with a focus on electricity generation)
- electrification and (in two of the scenarios) use of renewable electricity-based synthetic fuels (especially in the transport and industry sector)
In addition, some scenarios use controversially:
- final energy demand reductions through behavioral changes (modal shift in transport, changes in eating and heating habits)
- net imports of electricity from renewable sources or of bioenergy
- use of carbon capture and storage (CCS) technology to reduce industry sector GHG emissions (including cement production)
Potential co-benefits for Germany include increased energy security, higher competitiveness of and global business opportunities for companies, job creation, stronger GDP growth, smaller energy bills for households, and less air pollution.
2015 Fraunhofer ISE study
Using the model REMod-D (Renewable Energy Model – Germany), this 2015 Fraunhofer ISE study investigates several system transformation scenarios and their related costs. The guiding question of the study is: "how can a cost-optimised transformation of the German energy system — with consideration of all energy carriers and consumer sectors — be achieved while meeting the declared climate protection targets and ensuring a secure energy supply at all times." Carbon capture and storage (CCS) is excluded from the scenarios. An energy scenario emitting 85% less CO2 emissions than 1990 levels is compared with a reference scenario, assumes that the German energy system operates in 2050 the same way as it does today. Primary energy supply drops 42%. The total costs depend on the future prices for carbon and oil. If the penalty for CO2 emissions increases to €100/tonne by 2030 and thereafter remains constant and fossil fuel prices increase annually by 2%, then the total cumulative costs of today's energy system are 8% higher than the costs required for the minus 85% scenario up to 2050. The report notes:
From the macroeconomic perspective, the transformation of Germany's energy system demands a significant shift in cash flow, moving the cash spent on energy imports today to spend it instead on new investments in systems, their operation and maintenance. In this respect a transformed energy system requires a large expenditure for local added value, a factor which also does not appear in the shown cost analysis.
2015 DIW study
A 2015 study uses DIETER or Dispatch and Investment Evaluation Tool with Endogenous Renewables, developed by the German Institute for Economic Research (DIW), Berlin, Germany. The study examines the power storage requirements for renewables uptake ranging from 60% to 100%. Under the scenario of 80% (the German government target for 2050), grid storage requirements remain moderate and other options on both the supply side and demand side offer flexibility at low cost. Storage plays a role in the provision of reserves. Storage becomes more pronounced under higher shares of renewables, but strongly depends on the costs and availability of other flexibility options, particularly on biomass availability. The model is fully described in the study report.
2016 acatech study
A 2016 acatech-lead study focused on "flexibility technologies" used to balance the fluctuations inherent in power generation from wind and photovoltaics. Set in 2050, several scenarios use gas power plants to stabilise the energy system, ensuring supply security during several weeks of low wind and solar radiation. Other scenarios investigate a 100% renewable system and show these to be possible but costly. Flexible consumption and storage control (demand-side management) in households and the industrial sector is the cost-efficient means of balancing short-term power fluctuations. Long-term storage systems, based on power-to-X, are only viable if carbon emissions are to be reduced by more than 80%. The study notes:
Assuming that the price of emissions allowances in 2050 will significantly surpass its current level, a power generation system boasting a high percentage of wind and photovoltaics will, as a rule, come cheaper than a system dominated by fossil fuel power plants.
2016 Stanford University study
The Atmosphere/Energy Program at Stanford University has developed roadmaps for 139 countries to achieve energy systems powered only by wind, water, and sunlight (WWS) by 2050. Total end-use energy drops from 375.8 GW for business-as-usual to 260.9 GW under a fully renewable transition. Load shares in 2050 would be: on-shore wind 35%, off-shore wind 17%, wave 0.08%, geothermal 0.01%, hydro-electric 0.87%, tidal 0%, residential PV 6.75%, commercial PV 6.48%, utility PV 33.8%, and concentrating solar power 0%. The study also assess avoided air pollution, eliminated global climate change costs, and net job creation.
See also
- Dunkelflaute
- Electricity sector in Germany
- Energieeinsparverordnung – German building energy regulations
- Energy in Germany
- Energy modeling
- European Green Deal
- Federal Network Agency
- Fossil fuel phase-out
- The Fourth Revolution: Energy
- German Renewable Energy Act
- German Solar Industry Association
- Germany National Renewable Energy Action Plan
- KfW IPEX-Bank
- List of countries by renewable electricity production
- Low-carbon economy
- Passivhaus
- Renewable energy commercialization
- Renewable energy in Germany
- Renewable energy in the European Union
- Soft energy path
- Wildpoldsried
- Greenpeace Energy
References
- ^ The Energy of the Future: Fourth "Energy Transition" Monitoring Report — Summary (PDF). Berlin, Germany: Federal Ministry for Economic Affairs and Energy (BMWi). November 2015. Retrieved 2017-11-18.
- Hillebrandt, Katharina; et al., eds. (2015). Pathways to deep decarbonization in Germany (PDF). Sustainable Development Solutions Network (SDSN) and Institute for Sustainable Development and International Relations (IDDRI). Archived from the original (PDF) on 2016-09-09. Retrieved 2016-04-28.
- "Atomkraftwerke in Deutschland". Bundesministerium für Umwelt, Naturschutz, nukleare Sicherheit und Verbraucherschutz (in German). Archived from the original on 2022-03-24. Retrieved 2022-03-26.
- "Kernkraft". Archived from the original on 2020-11-30. Retrieved 2020-12-26.
- "Bund und Länder einigen sich auf Stilllegungspfad zum Kohleausstieg". Bundesregierung. 2020-01-16.
- "What does the coalition deal mean for renewables, coal and the power market in Germany?". Clean Energy Wire. 2021-12-08. Retrieved 2024-07-04.
- "Reflections on Germany's nuclear phaseout - Nuclear Engineering International". www.neimagazine.com. Archived from the original on 2020-06-09. Retrieved 2020-05-28.
- Jungjohann, Arne; Morris, Craig (June 2014). The German coal conundrum (PDF). Washington, DC, USA: Heinrich Böll Stiftung. Archived from the original (PDF) on 2016-10-10. Retrieved 2016-10-07.
The term Energiewende, the Country's transition away from nuclear power to renewables with lower energy consumption, is commonly used in English.
- Krause, Florentin; Bossel, Hartmut; Müller-Reißmann, Karl-Friedrich (1980). Energie-Wende: Wachstum und Wohlstand ohne Erdöl und Uran [Energy transition: growth and prosperity without petroleum and uranium] (PDF) (in German). Germany: S Fischer Verlag. ISBN 978-3-10-007705-9. Archived from the original (PDF) on 2016-09-14. Retrieved 2016-06-14.
- Jacobs, David (2012). "The German Energiewende: history, targets, policies and challenges". Renewable Energy Law and Policy Review. 3 (4): 223–233. In support of the claim that Krause et al. (1980) was the first use of the term Energiewende.
- "Origin of the term "Energiewende"". Archived from the original on 2018-10-21. Retrieved 2017-03-09.
- Paulitz, Henrik. "Dezentrale Energiegewinnung — Eine Revolutionierung der gesellschaftlichen Verhältnisse" [Decentralized energy production — a revolution in social relations]. International Physicians for the Prevention of Nuclear War (IPPNW) (in German). Retrieved 2016-06-14.
- "Mit Bürgerengagement zur Energiewende" [With citizen involvement for the Energiewende]. Deutscher Naturschutzring (in German). 2011. Archived from the original on 2016-08-12. Retrieved 2016-06-14.
- Federal Ministry of Economics and Technology (BMWi); Federal Ministry for the Environment, Nature Conservation and Nuclear Safety (BMU) (2010-09-28). Energy concept for an environmentally sound, reliable and affordable energy supply (PDF). Berlin, Germany: Federal Ministry of Economics and Technology (BMWi). Archived from the original (PDF) on 2016-10-06. Retrieved 2016-05-01.
- The Federal Government's energy concept of 2010 and the transformation of the energy system of 2011 (PDF). Bonn, Germany: Federal Ministry for the Environment, Nature Conservation, and Nuclear Safety (BMU). October 2011. Archived from the original (PDF) on 2016-10-06. Retrieved 2016-06-16.
- "A Tale of Two Decarbonizations". The Breakthrough Institute. Retrieved 2020-07-21.
- "Letter from Sigmar Gabriel to Stefan Loevfen" (PDF). 2014-10-13.
- Hansen, James (2009). Storms of my grandchildren. Bloomsbury Publishing USA. ISBN 978-1608195022.
- "Deutschlands Energiewende – Ein Gemeinschaftswerk für die Zukunft" (PDF). Ethik-Kommission Sichere Energieversorgung. 2011-05-30.
- ^ Traufetter, Gerald; Schultz, Stefan; Jung, Alexander; Dohmen, Frank (2019-05-13). "German failure on the road to a renewable future". Der Spiegel International. Hamburg, Germany. Retrieved 2021-02-16.
- "Verflechtung und Integration | Internationale Politik". internationalepolitik.de. Retrieved 2022-10-18.
- "Overview CDU/CSU and SPD present Coalition Agreement – 55% to 60% renewables by 2035 and more". German Energy Blog. Germany. 2013-11-27. Retrieved 2016-06-16.
- Buchan, David (June 2012). The Energiewende — Germany's gamble (PDF). Oxford, UK: Oxford Institute for Energy Studies. ISBN 978-1-907555-52-7. Retrieved 2016-05-12.
- Agora Energiewende (2015). Understanding the Energiewende: FAQ on the ongoing transition of the German power system (PDF). Berlin, Germany: Agora Energiewende. Archived from the original (PDF) on 2016-06-02. Retrieved 2016-04-29.
- Jungjohann, Arne; Morris, Craig (2016). Energy Democracy. Germany's Energiewende to Renewables. Palgrave Macmillan. ISBN 978-3-319-31890-5.
- acatech; Lepoldina; Akademienunion, eds. (2016). Consulting with energy scenarios: requirements for scientific policy advice (PDF). Berlin, Germany: acatech — National Academy of Science and Engineering. ISBN 978-3-8047-3550-7. Archived from the original (PDF) on 2016-11-09. Retrieved 2016-11-09.
- Schiermeier, Quirin (2013-04-10). "Renewable power: Germany's energy gamble: an ambitious plan to slash greenhouse-gas emissions must clear some highly technical and economic hurdles". Nature. doi:10.1038/496156a. Retrieved 2016-05-01.
- ^ Curry, Andrew (2019-03-27). "Germany faces its future as a pioneer in sustainability and renewable energy". Nature. 567 (7749): S51–S53. Bibcode:2019Natur.567S..51C. doi:10.1038/d41586-019-00916-1. PMID 30918376.
- "Sixth 'Energy Transition' Monitoring Report – The Energy of the Future, Federal Ministry for Economic Affairs and Energy, June 2018
- Overview of legislation governing Germany's energy supply system: key strategies, acts, directives, and regulations / ordinances (PDF). Berlin, Germany: Federal Ministry of Economic Affairs and Energy (BMWi). May 2016. Archived from the original (PDF) on 2016-10-06. Retrieved 2016-04-29.
- ^ "Germany's energy transformation Energiewende". The Economist. 2012-07-28. Retrieved 2016-06-14.
- Latsch, Gunther; Seith, Anne; Traufetter, Gerald (2014-01-30). "Gone with the wind: weak returns cripple German renewables". Der Spiegel. Retrieved 2016-06-14.
- "Troubled turn: Germany's national energy project is becoming a cause for disunion". The Economist. 2013-02-07. Retrieved 2016-06-14.
- Electricity prices for industrial consumers Eurostat, October 2015
- Electricity prices (table) Eurostat, October 2016
- ^ Making a success of the energy transition: on the road to a secure, clean and affordable energy supply (PDF). Berlin, Germany: Federal Ministry for Economic Affairs and Energy (BMWi). September 2015. Retrieved 2016-06-07.
- Agora Energiewende (2013). 12 insights on Germany's Energiewende: a discussion paper exploring key challenges for the power sector (PDF). Berlin, Germany: Agora Energiewende. Retrieved 2016-04-29.
- Agora Energiewende (2015). The role of emissions trading in the energy transition: perspectives and limitations on current reform proposals (PDF). Berlin, Germany: Agora Energiewende. Retrieved 2016-04-29.
- Agora Energiewende (2016). Eleven principles for a consensus on coal: concept for a stepwise decarbonisation of the German power sector (Short version) (PDF). Berlin, Germany: Agora Energiewende. Retrieved 2016-04-29.
- SPIEGEL, Melanie Amann, Gerald Traufetter, DER (2019-03-19). "The Climate Activist vs. the Economics Minister: 'My Generation Has Been Fooled' – DER SPIEGEL – International". Der Spiegel. Retrieved 2020-07-21.
{{cite news}}
: CS1 maint: multiple names: authors list (link) - Quaschning, Volker (2016-06-20). Sektorkopplung durch die Energiewende: Anforderungen an den Ausbau erneuerbarer Energien zum Erreichen der Pariser Klimaschutzziele unter Berücksichtigung der Sektorkopplung [Sector coupling via the Energiewende: requirements for the development of renewable energy to achieve the Paris climate protection goals, taking into account sector coupling] (PDF) (in German). Berlin, Germany: Hochschule für Technik und Wirtschaft Berlin. Retrieved 2016-06-23.
- Agora Energiewende (2014). Electricity storage in the German energy transition: analysis of the storage required in the power market, ancillary services market and the distribution grid (PDF). Berlin, Germany: Agora Energiewende. Retrieved 2016-04-29.
- Schill, Wolf-Peter; Diekmann, Jochen; Zerrahn, Alexander (2015). "Power storage: an important option for the German energy transition" (PDF). DIW Economic Bulletin. 5 (10): 137–146. ISSN 2192-7219. Retrieved 2016-06-09.
- Shellenberger, Michael. "The Reason Renewables Can't Power Modern Civilization Is Because They Were Never Meant To". Forbes. Retrieved 2020-07-21.
- Agora Energiewende (2014). Benefits of energy efficiency on the German power sector: summary of key findings from a study conducted by Prognos AG and IAEW (PDF). Berlin, Germany: Agora Energiewende. Archived from the original (PDF) on 2016-06-02. Retrieved 2016-04-29.
- Agora Energiewende (2015). Increased integration of the Nordic and German electricity systems: modelling and assessment of economic and climate effects of enhanced electrical interconnection and the additional deployment of renewable energies (PDF). Berlin, Germany: Agora Energiewende. Retrieved 2016-04-29.
- Schiermeier, Quirin (2013-04-10). "Renewable power: Germany's energy gamble: an ambitious plan to slash greenhouse-gas emissions must clear some high technical and economic hurdles". Nature. doi:10.1038/496156a. Retrieved 2016-05-01.
- Strunz, Sebastian (2014). "The German energy transition as a regime shift". Ecological Economics. 100: 150–158. Bibcode:2014EcoEc.100..150S. doi:10.1016/j.ecolecon.2014.01.019. hdl:10419/76875. S2CID 41888814.
- Schmid, Eva; Knopf, Brigitte; Pechan, Anna (2015). Who puts the German Energiewende into action?: characterizing arenas of change and implications for electricity infrastructure (PDF). Archived from the original (PDF) on 2016-06-02. Retrieved 2016-05-01.
- "National Action Plan on Energy Efficiency (NAPE): making more out of energy". Federal Ministry for Economic Affairs and Energy (BMWi). Retrieved 2016-06-07.
- Making more out of energy: National Action Plan on Energy Efficiency (PDF). Berlin, Germany: Federal Ministry for Economic Affairs and Energy (BMWi). December 2014. Retrieved 2016-06-07.
- Löschel, Andreas; Erdmann, Georg; Staiß, Frithjof; Ziesing, Hans-Joachim (November 2015). Statement on the Fourth Monitoring Report of the Federal Government for 2014 (PDF). Germany: Expert Commission on the "Energy of the Future" Monitoring Process. Archived from the original (PDF) on 2016-08-05. Retrieved 2016-06-09.
- Oltermann, Philip (2016-10-11). "Germany takes steps to roll back renewable energy revolution". The Guardian. London, United Kingdom. Retrieved 2016-10-13.
- Chambers, Madeline (2015-10-07). "German cabinet agrees to costly underground power lines". Reuters. Retrieved 2016-10-20.
- "Energiewende: What do the new laws mean?". Clean Energy Wire (CLEW). Berlin, Germany. 2016-10-14. Retrieved 2016-11-08.
- Energiewende: Was bedeuten die neuen Gesetze? – 102/06-H-2016/DE [Energiewende: What do the new laws mean? — 102/06-H-2016/DE] (PDF) (in German). Berlin, Germany: Agora Energiewende. Retrieved 2016-11-08.
- "Energiewende: What do the new laws mean?". Clean Energy Wire (CLEW). Berlin, Germany. 2016-11-18. Retrieved 2016-11-22.
- Argyropoulos, Daniel; Godron, Philipp; Graichen, Patrick; Litz, Philipp; Pescia, Dimitri; Podewils, Christoph; Redl, Christian; Ropenus, Stephanie; Rosenkranz, Gerd (November 2016). Energiewende: What do the new laws mean?: Ten questions and answers about EEG 2017, the Electricity Market Act, and the Digitisation Act — 103/07-H-2016/EN (PDF). Berlin, Germany: Agora Energiewende. Retrieved 2016-11-22.
- Klimaschutzplan 2050: Kabinettbeschluss vom 14. November 2016 [Climate protection plan 2050: Cabinet decision of 14 November 2016] (PDF) (in German). Berlin, Germany: Bundesministerium für Umwelt, Naturschutz, Bau und Reaktorsicherheit (BMUB). 2016-11-14. Archived from the original (PDF) on 2017-09-19. Retrieved 2016-11-17.
- ^ Climate Action Plan 2050: Principles and goals of the German government's climate policy (PDF). Berlin, Germany: Bundesministerium für Umwelt, Naturschutz, Bau und Reaktorsicherheit (BMUB). 2016-11-14. Archived from the original (PDF) on 2017-12-15. Retrieved 2016-11-17. This document is not an extract translated from the official plan.
- ^ Amelang, Sören; Wehrmann, Benjamin; Wettengel, Julian (2016-11-17). "Germany's Climate Action Plan 2050". Clean Energy Wire (CLEW). Berlin, Germany. Retrieved 2016-11-15.
- Egenter, Sven; Wehrmann, Benjamin (2016-12-15). "Experts call for CO2 price to retain Energiewende's credibility". Clean Energy Wire (CLEW). Berlin, German. Retrieved 2016-12-15.
- Die Energie der Zukunft: Fünfter Monitoring-Bericht zur Energiewende: Berichtsjahr 2015 [The energy of the future: Fifth monitoring report for the Energiewende: Report year 2015] (PDF) (in German). Berlin, Germany: Federal Ministry for Economic Affairs and Energy (BMWi). December 2016. Retrieved 2016-12-15.
- "COP25: When it comes to climate protection, Germany still has a lot to do | DW | 11 December 2019". Deutsche Welle. Retrieved 2019-12-12.
- "Urgent rethink required as Germany's energy transition stalls". Clean Energy Wire. Retrieved 2019-12-12.
- "Germans fall out of love with wind power". Financial Times. 2019-11-17. Retrieved 2019-12-12.
- "German wind energy stalls amid public resistance and regulatory hurdles | DW | 4 September 2019". Deutsche Welle. Retrieved 2019-12-12.
- "INFOGRAPHIC: Can Germany's Energiewende ensure supply security?". EurActiv.com. 2016-06-21. Retrieved 2017-02-01.
- "Mission-oriented R&I policies: In-depth case studies: Energiewende" (PDF).
- "Land set to become "new currency" of Germany's energy transition – study". Clean Energy Wire. Retrieved 2021-10-05.
- ^ "Germany 2020 – Analysis". IEA. 2020-02-19. Retrieved 2020-03-26.
- "German commission proposes coal exit by 2038". Clean Energy Wire. 2019-01-23. Retrieved 2022-01-21.
- "Speech by Federal Chancellor Angela Merkel at the 49th World Economic Forum Annual Meeting in Davos on 23 January 2019". Home Page. Retrieved 2020-05-18.
- Michalopoulos, Sarantis (2021-03-19). "German MEP: Nord Stream 2 needs a 'European' perspective". www.euractiv.com. Retrieved 2021-03-19.
- "EU indecision over gas as green investment imperils supply security – German utilities". Clean Energy Wire. 2021-04-22. Retrieved 2021-04-25.
- "German Economy Minister – Do not want imported nuclear power to make up for coal phase-out: ZDF". Reuters. 2019-01-28. Retrieved 2021-06-16.
- Kurmayer, Nikolaus J. (2021-11-01). "Green MEP: Germany 'may need some additional gas turbines' to stabilise renewables". www.euractiv.com. Retrieved 2021-11-01.
- "Germany to fall short of 2020 climate goals: report | DW | 6 February 2019". Deutsche Welle. Retrieved 2020-02-28.
- "Climate goal failure warrants high Energiewende priority- gov advisors". Clean Energy Wire. 2018-06-27. Retrieved 2020-02-28.
- "Germany set to reach original 2020 climate target due to pandemic – researchers". Clean Energy Wire. 2020-08-14. Retrieved 2020-09-11.
- "StackPath". www.uniper.energy. Retrieved 2020-05-28.
- nicholasnhede (2020-11-19). "RWE gas-fired plant to supply German nuclear decommissioning project". Power Engineering International. Retrieved 2020-11-19.
- Proctor, Darrell (2020-06-02). "Germany Brings Last New Coal Plant Online". POWER Magazine. Retrieved 2021-10-24.
- "Bavaria gets new gas-fired power plant to ensure supply security". Clean Energy Wire. 2021-02-11. Retrieved 2021-03-20.
- "Supply security: Uniper coal plant needs to stay in reserve a while longer". Clean Energy Wire. 2021-06-02. Retrieved 2021-06-03.
- Anonym. "Not enough electricity for the citizens: Schongau reserve power plant in use for the first time". newsrnd.com. Retrieved 2022-02-14.
- "Unabhängige Wissenschaft?". www.igte.uni-stuttgart.de. Archived from the original on 2021-06-01. Retrieved 2021-10-24.
- Wetzel, Daniel (2021-05-31). "Wegen Zustimmung zum Atomausstieg: Vorwürfe gegen Ethikkommission". DIE WELT. Retrieved 2021-06-03.
- "Germany: Coal tops wind as primary electricity source | DW | 13 September 2021". Deutsche Welle. Retrieved 2021-09-16.
- "Home". 1 Milliarde Tonnen (in German). Retrieved 2021-10-19.
- ^ Shellenberger, Michael (2021-09-14). "Skyrocketing Natural Gas Prices Create New Opportunity for Nuclear Energy". michaelshellenberger.substack.com. Retrieved 2021-09-16.
- "Germany to widely miss 2030 climate target – draft govt report". Clean Energy Wire. 2021-08-20. Retrieved 2021-10-13.
- "Government projection report confirms Germany clearly off-track from 2030 climate target". Clean Energy Wire. 2021-10-19. Retrieved 2021-10-28.
- Kurmayer, Nikolaus J. (2021-10-13). "Intellectuals urge Germany to keep nuclear plants online". www.euractiv.com. Retrieved 2021-10-13.
- "The Clean Energy Revolution: from fossil fuels to renewables + nuclear". Clean Energy Revolution. Retrieved 2021-10-13.
- "The catch with Germany's green transformation". Politico. 2021-11-25. Retrieved 2021-11-29.
- "Strommix 2022: Stromerzeugung in Deutschland". STROM-REPORT (in German). Retrieved 2022-08-03.
- "Germany off course to 2030 climate target – think tank". Clean Energy Wire. 2022-01-07. Retrieved 2022-01-15.
- Millard, Rachel (2022-01-08). "Germany's meltdown over nuclear power risks a costly winter". The Telegraph. ISSN 0307-1235. Retrieved 2022-01-15.
- Kurmayer, Nikolaus J. (2022-01-24). "Germany takes firm pro-gas stance in green taxonomy feedback to EU". www.euractiv.com. Retrieved 2022-01-25.
- "Herne energy site: plans for one of the world's most state-of-the-art gas and steam power plants are in full swing". Archived from the original on 2021-04-18. Retrieved 2022-10-10.
It is also precisely at this point in time that the last nuclear power plants are to be removed from the grid, so that the Herne gas and steam power plant could benefit from rising wholesale electricity prices.
- "German emissions fall by a fifth amid stagnant industrial output". Financial Times. Retrieved 2024-04-16.
- Eddy, Melissa (2022-06-19). "Germany will fire up coal plants again in an effort to save natural gas". The New York Times.
- "CDU-Vize Kretschmer hält Energiewende für gescheitert". Der Spiegel (in German). 2022-08-01. ISSN 2195-1349. Retrieved 2022-08-03.
- "Germany rethinks nuclear power exit due to threat of winter energy crunch". Financial Times. 2022-07-26. Retrieved 2022-08-03.
- "ZEIT ONLINE | Lesen Sie zeit.de mit Werbung oder im PUR-Abo. Sie haben die Wahl". www.zeit.de. Archived from the original on 2022-09-01. Retrieved 2022-09-01.
- "Duits dorp bij Roermond verliest strijd tegen bruinkoolmijn". nos.nl (in Dutch). 2022-10-14. Retrieved 2022-10-18.
- "Germany extends lifespan of all three nuclear power plants". Politico. 2022-10-17. Retrieved 2022-10-18.
- ^ "Germany | Electricity Trends". Ember. 2022-03-28. Retrieved 2024-07-04.
- Brinker, Lina-Sophie (2024-06-27). Entwicklung der spezifischen Treibhausgas-Emissionen des deutschen Strommix in den Jahren 1990 - 2023. Umweltbundesamt.
- "Habeck braucht Geld für Kraftwerke: Die nächsten 60 Milliarden fehlen - WELT". DIE WELT (in German). 2024-01-15. Retrieved 2024-01-15.
- "Übergang zu erneuerbaren Energien: Deutschland braucht 60 Milliarden Euro für Reservekraftwerke". www.merkur.de (in German). 2024-01-04. Retrieved 2024-01-16.
- "Germany outlines $17 bln plan to subsidise gas-to-hydrogen shift". Reuters.
- "Bundesregierung einigt sich auf Kraftwerksstrategie". tagesschau.de (in German). Retrieved 2024-02-06.
- "Germany has shut down its last three nuclear power plants, and some climate scientists are aghast". NBC News. 2023-04-18.
- "After scrapping nuclear reactors, Germany to spend billions on new gas power plants". Politico. 2024-02-05.
- "Bericht nach § 99 BHO zur Umsetzung der Energiewende im Hinblick auf die Versorgungssicherheit, Bezahlbarkeit und Umweltverträglichkeit der Stromversorgung" (PDF). Bundesrechnungshof. 2024-03-07.
- "Court of Auditors considers power supply jeopardised - energate messenger.com". www.energate-messenger.com. 2024-03-07. Retrieved 2024-04-03.
- richardollington (2024-12-04). "Restarting Germany's Reactors: Feasibility and Schedule". Radiant Energy Group. Retrieved 2024-12-10.
- "Electricity Prices in Europe – Who Pays the Most?". Stromvergleich. Retrieved 2016-09-05.
- "Gas-fired power generation reaches record high in Germany". Clean Energy Wire. 2020-02-26. Retrieved 2020-02-29.
- "Does renewables pioneer Germany risk running out of power?". Reuters. 2019-07-19. Retrieved 2020-02-29.
- Lauber, Volkmar; Jacobsson, Staffan (2016). "The politics and economics of constructing, contesting and restricting socio-political space for renewables – The German Renewable Energy Act". Environmental Innovation and Societal Transitions. 18: 147–163. Bibcode:2016EIST...18..147L. doi:10.1016/j.eist.2015.06.005.
- "Components of the German electricity price". May 2016. Retrieved 2016-08-15.
- Bruninx, Kenneth; Madzharov, Darin; Delarue, Erik; D'haeseleer, William (2013). "Impact of the German nuclear phase-out on Europe's electricity generation — a comprehensive study". Energy Policy. 60: 251–261. Bibcode:2013EnPol..60..251B. doi:10.1016/j.enpol.2013.05.026. Retrieved 2016-05-12.
- "Polish academics urge end to Germany's nuclear phaseout – World Nuclear News". www.world-nuclear-news.org. Retrieved 2019-06-27.
- Severin, Thorsten; Bryan, Victoria (2014-10-12). "Germany says can't exit coal-fired energy at same time as nuclear". reuters. Retrieved 2016-06-14.
- Gabriel, Sigmar (2014-10-13). "Dear Stefan Löfven – Letter to Swedish Prime Minister from Sigmar Gabriel" (PDF). Altinget. Retrieved 2016-06-14.
- Stam, Claire (2019-04-09). "Gas, a prominent guest at German energy transition event". euractiv.com. Retrieved 2019-07-10.
- "Germany's dependence on imported fossil fuels". Clean Energy Wire. 2015-06-22. Retrieved 2019-07-10.
- "Gas wars part one: let's be honest about Germany's growing dependence on fossil gas". Energy Transition. 2019-03-19. Retrieved 2019-07-10.
- "Nord Stream 2 pipeline row highlights Germany's energy dependence on Russia | DW | 4 February 2019". Deutsche Welle. Retrieved 2019-07-10.
- Oroschakoff, Kalina (2018-03-23). "Germany's green energy shift is more fizzle than sizzle". Politico. Retrieved 2019-07-10.
- Hook, Leslie; Thomas, Nathalie; Tighe, Chris (2019-10-01). "How Britain ended its coal addiction". Financial Times. Retrieved 2020-07-21.
- Wacket, Markus (2021-03-30). "Germany's energy drive criticised over expense, risks". Reuters. Retrieved 2021-06-16.
- Jarvis S, Deschenes O, Jha A (June 2022). "The Private and External Costs of Germany's Nuclear Phase-Out". Journal of the European Economic Association. 20 (3): 1311–1346. doi:10.1093/jeea/jvac007.
- "Letter: Germany should postpone nuclear exit to help climate". Financial Times. 2021-09-27. Retrieved 2021-09-28.
- Emblemsvåg, Jan (2024-12-31). "What if Germany had invested in nuclear power? A comparison between the German energy policy the last 20 years and an alternative policy of investing in nuclear power". International Journal of Sustainable Energy. 43 (1). Bibcode:2024IJSEn..4355642E. doi:10.1080/14786451.2024.2355642. ISSN 1478-6451.
- Eddy, Melissa (2024-04-09). "German Business Is Tangled in Red Tape". The New York Times. Retrieved 2024-04-09.
- "Energiewende: Germany's planned transition to a low-carbon, nuclear-free economy". SDG16.plus.
- "Clean Energy Wire".
- "Germany's energy consumption in 2017". Energy Transition. 2018-01-11. Retrieved 2018-04-10.
- https://fas.org/sgp/crs/misc/R41603.pdf
- "Air pollution from biomass energy". 2011-03-17.
- Eartha Jane Melzer (2010-01-26). "Proposed biomass plant: Better than coal?". The Michigan Messenger. Archived from the original on 2010-02-05.
- Ukhanova, Mariya; Schoof, Nicolas; Neher, Lucas; Luick, Rainer (2018). "Balancing energy transition in Germany: how will it influence permanent grassland? A Delphi-study". Grassland Science in Europe. 23: 679–671.
- "Is Germany's Greenpeace Energy at peace selling natural gas?". Climate & Capital Media. 2021-03-11. Retrieved 2021-09-16.
- Amelang, Sören; Wettengel, Julian (2016-05-04). "Polls reveal citizens' support for Energiewende". Clean Energy Wire (CLEW). Berlin, Germany. Retrieved 2016-09-09.
- ^ Borchert, Lars (2015-03-10). "Germany between citizens' energy and Nimbyism". Clean Energy Wire (CLEW). Berlin, Germany. Retrieved 2016-09-09.
- "About one in two Germans is willing to financially participate in solar photovoltaic or wind power capacity". University of St Gallen. St Gallen, Switzerland. 2016-09-08. Retrieved 2016-09-09.
- Mühlenhoff, Jörg (December 2010). "Value creation for local communities through renewable energies: results of the study by the Institute for Ecological Economy Research (IÖW)" (PDF). Renews Special (46). Translated by Hill, Phil. ISSN 2190-3581. Archived from the original (PDF) on 2012-05-23. Retrieved 2016-08-05. See also Institut für ökologische Wirtschaftsforschung.
- "A powerplant in your neighborhood?: acceptance of power plants close to the home". 2014. Retrieved 2016-06-14.
- Amelang, Sören (2016-06-29). "The reform of the Renewable Energy Act: Germany's energy transition revamp stirs controversy over speed, participation". Clean Energy Wire (CLEW). Berlin, Germany. Retrieved 2016-07-02.
- University of Lüneburg; Nestle, Uwe (April 2014). Marktrealität von Bürgerenergie und mögliche Auswirkungen von regulatorischen Eingriffen — Eine Studie für das Bündnis Bürgerenergie e.V. (BBEn) und dem Bund für Umwelt und Naturschutz Deutschland e.V. (BUND) [Market reality of citizens energy and potential impact of regulatory intervention — A study for the Alliance for Citizens Energy (BBEn) and Friends of the Earth Germany (BUND)] (PDF) (in German). Archived from the original (PDF) on 2016-09-14. Retrieved 2016-09-09.
- "Akzeptanzumfrage 2014: 92 Prozent der Deutschen unterstützen den Ausbau Erneuerbarer Energien" [Acceptance survey 2014: 92 percent of Germans support the development of renewable energy]. Agentur für Erneuerbare Energien (Renewable Energies Agency). Berlin, Germany. Retrieved 2016-06-14.
-
REN21 (2015). Renewables 2015: global status report (PDF). Paris, France: REN21 Secretariat. ISBN 978-3-9815934-6-4. Retrieved 2016-06-14.
{{cite book}}
: CS1 maint: numeric names: authors list (link) - Morris, Craig (2015-02-24). "Few new German energy co-ops in 2014". Energy Transition: The German Energiewende. Berlin, Germany. Archived from the original on 2016-09-11. Retrieved 2016-08-04.
- "Share of German citizen renewable energy shrinking". Energy Transition. 2018-02-07. Retrieved 2018-02-26.
- ^ "Winds of change push German power grid to brink | DW | 11 March 2020". Deutsche Welle. Retrieved 2020-03-26.
- "An ill wind blows for the onshore power industry". Politico. 2019-08-20. Retrieved 2020-02-28.
- "Against the wind: Local opposition to the German 'Energiewende'". 2015.
- Dieckhoff, Christian; Leuschner, Anna, eds. (November 2016). Die Energiewende und ihre Modelle: Was uns Energieszenarien sagen können – und was nicht [The Energiewende and its models: What energy scenarios can tell us – and what not] (in German). Bielefeld, Germany: transcript Verlag. ISBN 978-3-8376-3171-5.
- WWF Germany (2009). Blueprint Germany: a strategy for a climate safe 2050 (PDF). Berlin, Germany: WWF Germany. Archived from the original (PDF) on 2016-10-06. Retrieved 2016-05-01.
- "Climate-friendly, reliable, affordable: 100% renewable electricity supply by 2050" (Press release). Berlin, Germany: German Advisory Council on the Environment (SRU). 2010-05-05. Archived from the original on 2016-11-12. Retrieved 2016-11-11.
- Pathways towards a 100 % renewable electricity system — Special report (PDF). Berlin, Germany: German Advisory Council on the Environment (SRU). October 2011. Retrieved 2016-11-11. (Public domain, see PDF metadata)
- Hillebrandt, Katharina; et al., eds. (2015). Pathways to deep decarbonization in Germany (PDF). Sustainable Development Solutions Network (SDSN) and Institute for Sustainable Development and International Relations (IDDRI). Archived from the original (PDF) on 2016-09-09. Retrieved 2016-04-28.
- Henning, Hans-Martin; Palzer, Andreas (2014). "A comprehensive model for the German electricity and heat sector in a future energy system with a dominant contribution from renewable energy technologies — Part I: Methodology". Renewable and Sustainable Energy Reviews. 30: 1003–1018. Bibcode:2014RSERv..30.1003H. doi:10.1016/j.rser.2013.09.012.
- ^ Henning, Hans-Martin; Palzer, Andreas (2015). What will the energy transformation cost?: pathways for transforming the German energy system by 2050 (PDF). Freiburg, Germany: Fraunhofer Institute For Solar Energy Systems ISE. Retrieved 2016-04-29.
- Zerrahn, Alexander; Schill, Wolf-Peter (2015). A greenfield model to evaluate long-run power storage requirements for high shares of renewables — DIW discussion paper 1457 (PDF). Berlin, Germany: German Institute for Economic Research (DIW). ISSN 1619-4535. Retrieved 2016-07-07.
- ^ acatech; Lepoldina; Akademienunion, eds. (2016). Flexibility concepts for the German power supply in 2050: ensuring stability in the age of renewable energies (PDF). Berlin, Germany: acatech — National Academy of Science and Engineering. ISBN 978-3-8047-3549-1. Archived from the original (PDF) on 2016-10-06. Retrieved 2016-06-10.
- Lunz, Benedikt; Stöcker, Philipp; Eckstein, Sascha; Nebel, Arjuna; Samadi, Sascha; Erlach, Berit; Fischedick, Manfred; Elsner, Peter; Sauer, Dirk Uwe (2016). "Scenario-based comparative assessment of potential future electricity systems — A new methodological approach using Germany in 2050 as an example". Applied Energy. 171: 555–580. Bibcode:2016ApEn..171..555L. doi:10.1016/j.apenergy.2016.03.087.
- Jacobson, Mark Z; Delucchi, Mark A; Bauer, Zack AF; Goodman, Savannah C; Chapman, William E; Cameron, Mary A; Bozonnat, Cedric; Chobadi, Liat; Clonts, Hailey A; Enevoldsen, P; Erwin, Jenny R; Fobi, Simone N; Goldstrom, Owen K; Hennessy, Eleanor M; Liu, Jingyi; Lo, Jonathan; Meyer, Clayton B; Morris, Sean B; Moy, Kevin R; O'Neill, Patrick L; Petkov, Ivalin; Redfern, Stephanie; Schucker, Robin; Sontag, Michael A; Wang, Jingfan; Weiner, Eric; Yachanin, Alexander S (2016-10-24). 100% clean and renewable wind, water, and sunlight (WWS) all-sector energy roadmaps for 139 countries of the world (PDF). Retrieved 2016-11-23.
- Delucchi, Mark A; Jacobson, Mark Z; Bauer, Zack AF; Goodman, Savannah C; Chapman, William E (2016). Spreadsheets for 139-country 100% wind, water, and solar roadmaps. Retrieved 2016-07-26. Direct URL: xlsx-spreadsheets.
Further reading
- Energy Concept for an Environmentally Sound, Reliable and Affordable Energy Supply, 28 September 2010 (English translation of the German policy document)
- Morris, Craig; Jungjohann, Arne (2016). Energy democracy: Germany's Energiewende to renewables. Cham, Switzerland: Springer International Publishing. doi:10.1007/978-3-319-31891-2. ISBN 978-3-319-31890-5.
- Sturm, Christine (2020). Inside the Energiewende: Twists and Turns on Germany's Soft Energy Path. Cham, Switzerland: Springer. ISBN 978-3030427290.
External links
- Clean Energy Wire (CLEW) – a news service covering the energy transition in Germany
- Energy Topics – hosted by the Federal Ministry for Economic Affairs and Energy (BMWi)
- German Energy Blog – a legal blog covering the Energiewende
- German Energy Transition – a comprehensive website maintained by the Heinrich Böll Foundation
- Presentation (30:47) by Amory Lovins to the Berlin Energy Transition Dialogue 2016, 17–18 March 2016
- Strom-Report.de – a statistics website covering renewable energy topics as well as the energy transition in Germany