Recent decline in the global land evapotranspiration trend due to limited moisture supply

More than half of the solar energy absorbed by land surfaces is currently used to evaporate water. Climate change is expected to intensify the hydrological cycle and to alter evapotranspiration, with implications for ecosystem services and feedback to regional and global climate. Evapotranspiration changes may already be under way, but direct observational constraints are lacking at the global scale. Until such evidence is available, changes in the water cycle on land—a key diagnostic criterion of the effects of climate change and variability—remain uncertain. Here we provide a data-driven estimate of global land evapotranspiration from 1982 to 2008, compiled using a global monitoring network, meteorological and remote-sensing observations, and a machine-learning algorithm. In addition, we have assessed evapotranspiration variations over the same time period using an ensemble of process-based land-surface models. Our results suggest that global annual evapotranspiration increased on average by 7.1 ± 1.0 millimetres per year per decade from 1982 to 1997. After that, coincident with the last major El Niño event in 1998, the global evapotranspiration increase seems to have ceased until 2008. This change was driven primarily by moisture limitation in the Southern Hemisphere, particularly Africa and Australia. In these regions, microwave satellite observations indicate that soil moisture decreased from 1998 to 2008. Hence, increasing soil-moisture limitations on evapotranspiration largely explain the recent decline of the global land-evapotranspiration trend. Whether the changing behaviour of evapotranspiration is representative of natural climate variability or reflects a more permanent reorganization of the land water cycle is a key question for earth system science.

[1]  P. Sen Estimates of the Regression Coefficient Based on Kendall's Tau , 1968 .

[2]  M. Budyko,et al.  Climate and life , 1975 .

[3]  Robert C. Wolpert,et al.  A Review of the , 1985 .

[4]  Michael H. Unsworth,et al.  Review and synthesis , 1995, Philosophical Transactions of the Royal Society of London. Series A: Physical and Engineering Sciences.

[5]  D. Lawrence,et al.  Regions of Strong Coupling Between Soil Moisture and Precipitation , 2004, Science.

[6]  Edwin W. Pak,et al.  An extended AVHRR 8‐km NDVI dataset compatible with MODIS and SPOT vegetation NDVI data , 2005 .

[7]  S. Kanae,et al.  Global Hydrological Cycles and World Water Resources , 2006, Science.

[8]  T. Vesala,et al.  Towards a standardized processing of Net Ecosystem Exchange measured with eddy covariance technique: algorithms and uncertainty estimation , 2006 .

[9]  R. Betts,et al.  Detection of a direct carbon dioxide effect in continental river runoff records , 2006, Nature.

[10]  Naota Hanasaki,et al.  GSWP-2 Multimodel Analysis and Implications for Our Perception of the Land Surface , 2006 .

[11]  Martin Jung,et al.  Exploiting synergies of global land cover products for carbon cycle modeling , 2006 .

[12]  T. Huntington Evidence for intensification of the global water cycle: Review and synthesis , 2006 .

[13]  W. Cohen,et al.  Evaluation of fraction of absorbed photosynthetically active radiation products for different canopy radiation transfer regimes: methodology and results using Joint Research Center products derived from SeaWiFS against ground-based estimations. , 2006 .

[14]  S. Seneviratne,et al.  Land–atmosphere coupling and climate change in Europe , 2006, Nature.

[15]  Michael L. Roderick,et al.  On the attribution of changing pan evaporation , 2007 .

[16]  M. Heimann,et al.  Comprehensive comparison of gap-filling techniques for eddy covariance net carbon fluxes , 2007 .

[17]  Pascal Yiou,et al.  Summertime European heat and drought waves induced by wintertime Mediterranean rainfall deficit , 2007 .

[18]  P. Ciais,et al.  Changes in climate and land use have a larger direct impact than rising CO2 on global river runoff trends , 2007, Proceedings of the National Academy of Sciences.

[19]  W. Lucht,et al.  Causes of change in 20th century global river discharge , 2008 .

[20]  Laurence C. Smith,et al.  Climatic and anthropogenic factors affecting river discharge to the global ocean, 1951–2000 , 2008 .

[21]  N. Gobron,et al.  Uncertainty Estimates for the FAPAR Operational Products Derived from MERIS - Impact of Top-of-Atmosphere Radiance Uncertainties and Validation with Field Data , 2008 .

[22]  R. Jeu,et al.  Multisensor historical climatology of satellite‐derived global land surface moisture , 2008 .

[23]  D. Baldocchi ‘Breathing’ of the terrestrial biosphere: lessons learned from a global network of carbon dioxide flux measurement systems , 2008 .

[24]  Klaus Scipal,et al.  A possible solution for the problem of estimating the error structure of global soil moisture data sets , 2008 .

[25]  Martin Wild,et al.  Combined surface solar brightening and increasing greenhouse effect support recent intensification of the global land‐based hydrological cycle , 2008 .

[26]  Earth's Global Energy Budget , 2009 .

[27]  A. Bondeau,et al.  Towards global empirical upscaling of FLUXNET eddy covariance observations: validation of a model tree ensemble approach using a biosphere model , 2009 .

[28]  Dick Dee,et al.  Low‐frequency variations in surface atmospheric humidity, temperature, and precipitation: Inferences from reanalyses and monthly gridded observational data sets , 2010 .

[29]  J. Klomp,et al.  A review and synthesis , 2010 .

[30]  S. Seneviratne,et al.  Investigating soil moisture-climate interactions in a changing climate: A review , 2010 .

[31]  E. Latrubesse,et al.  The Late Miocene paleogeography of the Amazon Basin and the evolution of the Amazon River system , 2010 .