Abstract
Major droughts in the United States have heavily impacted the hydrologic system, negatively effecting energy and food production. Improved understanding of historical drought is critical for accurate forecasts. Data from global climate models (GCMs), commonly used to assess drought, cannot effectively evaluate local patterns because of their low spatial scale. This research leverages downscaled (~4 km grid spacing) temperature and precipitation estimates from nine GCMs’ data under the business-as-usual scenario (Representative Concentration Pathway 8.5) to examine drought patterns. Drought severity is estimated using the Palmer Drought Severity Index (PDSI) with the Thornthwaite evapotranspiration method. The specific objectives were (1) To reproduce historical (1966–2005) drought and calculate near-term to future (2011–2050) drought patterns over the conterminous USA. (2) To uncover the local variability of spatial drought patterns in California between 2012 and 2018 using a network-based approach. Our estimates of land proportions affected by drought agree with the known historical drought events of the mid-1960s, late 1970s to early 1980s, early 2000s, and between 2012 and 2015. Network analysis showed heterogeneity in spatial drought patterns in California, indicating local variability of drought occurrence. The high spatial scale at which the analysis was performed allowed us to uncover significant local differences in drought patterns. This is critical for highlighting possible weak systems that could inform adaptation strategies such as in the energy and agricultural sectors.
Highlights
The Palmer Drought Severity Index (PDSI) was developed by Palmer [29] and is an extensively used method for quantifying drought severity
The current paper provides an assessment of drought as measured using the PDSI
We present an assessment of past and projected drought conditions over the CONUS as measured using PDSI
Summary
In the United States, significant historical drought events have had devastating effects on the hydrologic system, impacting energy generation and production [1,2], agriculture [3,4], water availability and associated infrastructure [5], and green infrastructure and vegetation health [6]. Understanding the spatial–temporal characteristics of drought onset is important in estimating probable propagation, spatially into nearby regions and progression to other dimensional categories [7]. It has been shown that drought conditions may, with time, extend to surrounding regions of similar climate patterns [8]. This will generally depend on the existing teleconnections of the climate regions in question
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