DOI: 10.3390/atmos17070649 ISSN: 2073-4433

Assessing Wind Power Potential, Multidimensional Wind Risk, and Development Suitability in Xinjiang, China, During 1979–2018

Mukeran Awa, Jiyun Tang, Yurui Wang, Yilixiati Aizezi, Lei Bai

Wind energy resource assessment in complex terrain regions requires high-resolution data and multidimensional risk evaluation beyond conventional wind speed climatology. This study uses a 40-year (1979–2018) WRF dynamical downscaling dataset assimilating over 2400 surface stations to assess wind power potential, long-term trends, diurnal characteristics, and extreme ramp events across nine terrain-defined wind zones in Xinjiang, Northwestern China. The capacity factor, equivalent full-load hours, and wind power density are computed at 100 m hub height and validated against 105 long-term stations. The domain-mean annual capacity factor is 0.08, but resources are concentrated in mountain-pass corridors where core-zone values reach 0.35–0.45. Seasonal asymmetry is pronounced: the windy season (April–August) contributes 57–69% of annual output depending on zone. Long-term trends are spatially differentiated, with a significant decline in southern basin zones and a significant increase in northern zones after 2006. Diurnal capacity factor profiles differ by zone type—nocturnal peaks in basin-margin corridors versus midday peaks in thermally driven passes—and remain phase-stable across four decades. Extreme ramp events concentrate in the windy season and decline in frequency after 2006, and sensitivity tests show that the main spatial pattern remains robust under 5%, 10%, and 15% hourly capacity factor change thresholds. These findings provide a quantitative basis for zone-specific wind power planning, storage sizing, and wind–solar complementarity strategies in arid continental regions with complex topography.

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