Climate change reshapes resource adequacy risks and optimal renewable energy siting in wind and solar energy systems
Qiu, L., R. Khorramfar, S. Wang, S. Amin and M.F. Howland (2026)
Nature Energy, (doi: 10.1038/s41560-026-02109-3)
Abstract / Summary:
Abstract: Deep decarbonization through weather-dependent wind and solar can introduce resource adequacy risks. Climate change compounds these risks by simultaneously reshaping renewable supply and electricity demand in synergistic, region-specific ways. Here we show that long-term adequacy challenges in decarbonized grids arise from the interplay between meteorological conditions and system design, driven by prolonged renewable generation shortfalls tied to fine-scale infrastructure siting choices.
Using 12-km climate projections with county-level power system optimization for New England and Texas, we find that climate change can increase resource inadequacy frequency up to fivefold by mid-century as rising cooling demand intersects with renewable resource declines or transmission bottlenecks. However, climate-informed planning provides cost-effective mitigation: Texas maintains adequacy at near-zero cost by pivoting wind capacity westward, while New England requires a modest 2.34% investment increase via solar and transmission expansion near load centres.
Our findings demonstrate that achieving climate-resilient, decarbonized grids requires moving beyond aggregate capacity goals towards high-resolution, climate-informed spatial planning that reveals localized siting opportunities.
Citation:
Qiu, L., R. Khorramfar, S. Wang, S. Amin and M.F. Howland (2026): Climate change reshapes resource adequacy risks and optimal renewable energy siting in wind and solar energy systems. Nature Energy, (doi: 10.1038/s41560-026-02109-3) (https://www.nature.com/articles/s41560-026-02109-3)