Summary/Abstract
This peer-reviewed study provides a detailed spatiotemporal characterization of the unprecedented 2019–2022 drought in central-east South America (CESA), explores the historical context of the event, assesses the exceptionality of the soil moisture anomalies, and describes the atmospheric mechanisms involved from a daily to multiyear timescale perspective. The authors find that a long-term soil drying trend resulting from a joint contribution of natural decadal variability in precipitation levels and increasing temperatures, predisposed CESA to experience during 2019–2022 a period of outstanding soil desiccation. Flash droughts led to large areas (~100.000km2) in CESA covered by record-breaking soil dryness. April 2020 witnessed the most severe conditions, when over 30% of the region experienced negative soil moisture anomalies larger than two standard deviations. Internal variability, particularly El Niño–Southern Oscillation, explained the dynamical forcing of this extreme drought. Large precipitation deficits and enhanced evaporation in CESA resulted from a coupled tropical and subtropical forcing associated to pronounced changes in the normal Walker and Hadley Cells’ circulation and to the establishment of a Rossby wave extending from west south Pacific towards South America.
These findings highlight the intricate interplay between different mechanisms in the occurrence of climate extremes, stressing the need for an adequate representation of the dynamical processes associated with daily-to-multiyear timescales in climate models.