Global warming is expected to incre

Global warming is expected to increase the frequency and intensity of
droughts in the 21st century, but the relative contributions from changes in moisture
supply (precipitation) versus evaporative demand (potential evapotranspiration;
PET) have not been comprehensively assessed. Using output from a suite of
general circulation model (GCM) simulations from version 5 of the state-of-the-art
Coupled Model Intercomparison Project (CMIP5), projected 21st-century drought
trends are investigated using an offline calculated index of soil moisture balance
(the Penman-Montieth based Palmer Drought Severity Index; PDSI). The PDSI
calculations are used to quantify the respective contributions of precipitation and
PET to projected drought trends. PDSI projections incorporating both precipitation
and PET changes from the GCMs vary regionally, with robust cross-model
drying in western North America, Central America, the Mediterranean, southern
Africa, and the Amazon and robust wetting occurring in the Northern Hemisphere
high latitudes and east Africa. These regional changes largely reflect the spatially
heterogeneous response of precipitation in the models, although drying in the
PDSI fields extends beyond the regions of reduced precipitation. This expansion
of drought areas is attributed to globally widespread increases in PET, caused by
increases in surface net radiation and the vapor pressure deficit. Increased PET
not only intensifies drying in areas where precipitation is already reduced, it also
drives areas into drought that would otherwise experience little drying or even
wetting from precipitation trends alone. This PET amplification effect is largest in the Northern Hemisphere mid-latitudes, and is especially pronounced in western
North America, Europe, and southeast China. Compared to PDSI projections
accounting for changes in precipitation only, the additional effect of increased PET
expands the percentage of global land area projected to experience significant drying
(PDSI≤ −1) by the end of the 21st-century from 23% to 43%. This integrated
accounting of both the supply and demand sides of the surface moisture balance
is therefore critical for characterizing the full range of projected drought risks tied
to increasing greenhouse gases and associated warming of the climate system.