Abstract
Abstract. Wind power is a vital ingredient for energy system transformation in line with the Paris Agreement. Limited land availability for onshore wind parks and higher wind speeds over sea make offshore wind energy increasingly attractive. While wind variability on different timescales poses challenges for planning and system integration, little focus has been given to multi-decadal variability. Our research therefore focuses on the characteristics of wind power on timescales exceeding ten years. Based on detrended wind data from the coupled centennial reanalysis CERA-20C, we calculate European long-term offshore wind power potential and analyze its variability focusing on three locations with distinct climatic conditions: the German North Sea, the Greek Mediterranean and the Portuguese Atlantic coast. We find strong indications for two significant multi-decadal modes that are identified consistently using two independent spectral analysis methods and in the 20-year running mean time series. In winter, the long-term evolution of wind power and the North Atlantic Oscillation (NAO) are directly linked in Germany and Portugal. While German North Sea wind power is positively correlated with the NAO (r=0.82), Portuguese Atlantic coast generation is anti-correlated with the NAO (r=-0.91). We evaluate the corresponding potential for spatial balancing in Europe and report substantial benefits from European cooperation. In particular, optimized allocations off the Portuguese Atlantic coast and in the German North Sea allow to reduce multi-decadal generation variance by a factor of 3–10 compared with country-level approaches.
Highlights
A fundamental transformation of our energy system towards renewable energy sources is inevitable (Rogelj et al, 2015)
We show the power spectral density (PSD) for three separated regions of Europe, namely (a) the Portuguese Atlantic Coast, (b) the Greek Mediterranean and (c) the German North Sea
P ≈ 8 years but will not be studied here as we focus on multi-decadal peaks
Summary
A fundamental transformation of our energy system towards renewable energy sources is inevitable (Rogelj et al, 2015). Wind power is an essential element of this transition: It is CO2 neutral during operation, costs are competitive (IRENA, 2019), and resource availability exceeds demand substantially Offshore wind power outperforms onshore wind power in some relevant aspects. Land availability and public acceptance is less limiting if wind turbines are placed offshore far away from residential areas. Until 2020 7.5 GW offshore wind power capacity had been installed in Germany and approximately 25 TWh of electricity were generated in 2019 (WindGuard, 2019). The German government has increased its offshore wind power capacity expansion target by 5 to 20 GW in 2030 (BMWi, 2020). The long-term strategy of the European Union includes 240–450 GW of offshore wind power capacity in 2050 (IEA, 2019), such that a better understanding of wind power generation variability is of great interest
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