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Assessing the national synergy potential of onshore and offshore renewable energy from the perspective of resources dynamic and complementarity

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  • Sun, Yanwei
  • Li, Ying
  • Wang, Run
  • Ma, Renfeng

Abstract

Intermittent renewable energy sources have been transformed from supplementary energy to dominant incremental alternative energy sources in the context of carbon neutrality target worldwide. For coastal countries, it is urgent to integrate abundant offshore energy into regional onshore renewable power sources economically and reliably considering the scarcity of land resources and negative environmental impacts. However, limited knowledge on the complex spatiotemporally synergy relationships between energy potential (onshore and offshore) is a barrier in making reasonable policies to promote collaborative development of onshore and offshore energies. This study presents a spatiotemporally explicit modelling framework for assessing the synergy potential characteristics of onshore and offshore renewable energy sources. The framework firstly estimates the technical potential of solar PV and wind energy across the country by using 40 years of hourly meteorological reanalysis data (1980–2020), and then investigates the long-term changes trend, stability, and complementarity of solar-wind energy potential spatiotemporally at both onshore and offshore sub-regions. We find that a considerable amount of solar PV and wind energy sources could be harnessed in China, and onshore potential across the country (178 PWh/yr) is approximate 20 times higher than offshore energy potential (8.9 PWh/yr). Overall, onshore solar-wind energy potentials exhibit statistically insignificant but slightly increasing trend over the past 40 years, while offshore wind potentials observe an opposite change trend for solar PV and wind energy production. Complementarity assessment showed the northeast and offshore parts of China present high complementarity effects for hourly and daily power production of solar-wind systems. Furthermore, inter-regional combination between offshore and onshore northwest regions also exhibits promising synergy effect for renewable energy power output. The results on resources dynamic and complementarity highlight the advantage of interregional resources cooperative configuration and electric power grid interconnections. The analysis performed in this paper could provide a global picture for the integration planning and collaborative development strategies formulation of on-/offshore renewable energy across the country.

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  • Sun, Yanwei & Li, Ying & Wang, Run & Ma, Renfeng, 2023. "Assessing the national synergy potential of onshore and offshore renewable energy from the perspective of resources dynamic and complementarity," Energy, Elsevier, vol. 279(C).
    • Handle: RePEc:eee:energy:v:279:y:2023:i:c:s0360544223015001
    DOI: 10.1016/j.energy.2023.128106
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    2. Yuanyuan Liu & Hao Zhang & Pengcheng Guo & Chenxi Li & Shuai Wu, 2024. "Optimal Scheduling of a Cascade Hydropower Energy Storage System for Solar and Wind Energy Accommodation," Energies, MDPI, vol. 17(11), pages 1-23, June.

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