Abstract
Spatially compounding extremes pose substantial threats to globally interconnected socio-economic systems. Here we use multiple large ensemble simulations of the high-emissions scenario to show increased risk of compound droughts during the boreal summer over ten global regions. Relative to the late twentieth century, the probability of compound droughts increases by ~40% and ~60% by the middle and late twenty-first century, respectively, with a disproportionate increase in risk across North America and the Amazon. These changes contribute to an approximately ninefold increase in agricultural area and population exposure to severe compound droughts with continued fossil-fuel dependence. ENSO is the predominant large-scale driver of compound droughts with 68% of historical events occurring during El Niño or La Niña conditions. With ENSO teleconnections remaining largely stationary in the future, a ~22% increase in frequency of ENSO events combined with projected warming drives the elevated risk of compound droughts. The co-occurrence of drought across different regions will have far-reaching effects on global agriculture and food supply. Model projections show an increased likelihood of these compound droughts under a high-emissions scenario, with a ninefold increase of farm land and population exposure.
Highlights
Compound extremes pose substantial threats to globally interconnected socialeconomic systems
Given the increasing global connectivity of socio-economic systems, understanding the historical characteristics of compound droughts and anticipating their changes in a future warmer climate is important for a broad suite of interconnected, climate-sensitive sectors[7]
The projected increase in agricultural exposure to compound droughts highlights the higher likelihood of simultaneous production shocks across multiple breadbaskets in the future period that could affect global food availability and security
Summary
Droughts are associated with a range of environmental, economic, and social impacts. Given the increasing global connectivity of socio-economic systems, understanding the historical characteristics of compound droughts and anticipating their changes in a future warmer climate is important for a broad suite of interconnected, climate-sensitive sectors[7]. The projected increase in agricultural exposure to compound droughts highlights the higher likelihood of simultaneous production shocks across multiple breadbaskets in the future period that could affect global food availability and security. The projected increases in the frequency and severity of compound droughts could disrupt the supply-demand network of such water intensive goods and thereby, can affect their availability and prices in global market. Our findings suggest that the regional teleconnections during El Nino or La Nina conditions do not change substantially, with increases mainly in the intensity of compound droughts in the future climate relative to historical climate These results imply that when ENSO events occur, they will likely affect the same geographical regions albeit with greater severity. Predictions of compound droughts and their impacts on agricultural areas and communities can facilitate international agribusiness industries to minimize the economic losses and insurance and re-insurance industries to design effective insurance schemes to reduce losses from simultaneous disasters
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