Abstract
Wind and solar electricity generation is projected to expand substantially over the next several decades due both to rapid cost declines as well as regulation designed to achieve climate targets. With increasing reliance on wind and solar generation, future energy systems may be vulnerable to previously underappreciated synoptic-scale variations characterized by low wind and/or surface solar radiation. Here we use western North America as a case study region to investigate the historical meteorology of weekly-scale “droughts” in potential wind power, potential solar power and their compound occurrence. We also investigate the covariability between wind and solar droughts with potential stresses on energy demand due to temperature deviations away human comfort levels. We find that wind power drought weeks tend to occur in late summer and are characterized by a mid-level atmospheric ridge centered over British Columbia and high sea level pressure on the lee side of the Rockies. Solar power drought weeks tend to occur near winter solstice when the seasonal minimum in incoming solar radiation co-occurs with the tendency for mid-level troughs and low pressure systems over the U.S. southwest. Compound wind and solar power drought weeks consist of the aforementioned synoptic pattern associated with wind droughts occurring near winter solstice when the solar resource is at its seasonal minimum. We find that wind drought weeks are associated with high solar power (and vice versa) both seasonally and in terms of synoptic meteorology, which supports the notion that wind and solar power generation can play complementary roles in a diversified energy portfolio at synoptic spatiotemporal scales over western North America.
Highlights
1.1 Energy system transitionGlobal energy consumption by human activities relies largely on fossil fuels that cause global warming and reduce air quality [1]
The purpose of this article was to document the climatology and synoptic meteorology associated with extreme reductions in wind and solar energy resource availability at the weekly timescale over western North America
We found that on the spatiotemporal scale selected, solar power varies 2/3rds more (i.e., 167%) than wind power and that solar variability is dominated by the seasonal cycle (99% of weekly-mean solar variability is explained linearly by the week-of-the-year) while wind power variability is dictated more by atmospheric circulation variability
Summary
Global energy consumption by human activities relies largely on fossil fuels that cause global warming and reduce air quality [1]. Governments throughout the world have pursued agreements to decarbonize their economies by implementing policies that encourage an accelerated transition away from fossil fuels [2]. Proposals to decarbonize economies often call for a higher share of total energy consumption to originate from electricity and for that electricity to be generated by non-greenhouse gas emitting technologies [3]. These technologies include wind, solar, nuclear, hydroelectric, and geothermal power, among others.
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