Extreme precipitation patterns and reductions of terrestrial ecosystem production across biomes

TitleExtreme precipitation patterns and reductions of terrestrial ecosystem production across biomes
Publication TypeJournal Article
Year of Publication2013
AuthorsZhang Y, M. Moran S, Nearing MA, Ponce-Campos GE, Huete A, Buda AR, Bosch DD, Gunter SA, Kitchen S.G., W. McNab H, Morgan JA, McClaran M.P., Montoya DS, Peters DC, Starks PJ
JournalJournal of Geophysical Research: Biogeosciences
Start Page148
Date Published01/2013
ARIS Log Number284598

Precipitation regimes are predicted to shift to more extreme patterns that are characterized by more heavy rainfall events and longer dry intervals, yet their ecological impacts on vegetation production remain uncertain across biomes in natural climatic conditions. This in situ study investigated the effects of these climatic conditions on aboveground net primary production (ANPP) by combining a greenness index from satellite measurements and climatic records during 2000–2009 from 11 long-term experimental sites in multiple biomes and climates. Results showed that extreme precipitation patterns decreased the sensitivity of ANPP to total annual precipitation (PT) at the regional and decadal scales, leading to decreased rain use efficiency (RUE; by 20% on average) across biomes. Relative decreases in ANPP were greatest for arid grassland (16%) and Mediterranean forest (20%) and less for mesic grassland and temperate forest (3%). The cooccurrence of heavy rainfall events and longer dry intervals caused greater water stress conditions that resulted in reduced vegetation production. A new generalized model was developed using a function of both PT and an index of precipitation extremes and improved predictions of the sensitivity of ANPP to changes in precipitation patterns. Our results suggest that extreme precipitation patterns have substantially negative effects on vegetation production across biomes and are as important as PT. With predictions of more extreme weather events, forecasts of ecosystem production should consider these nonlinear responses to altered extreme precipitation patterns associated with climate change.