GLEAM v3: satellite-based land evaporation and root-zone soil moisture

Abstract. The Global Land Evaporation Amsterdam Model (GLEAM) is a set of algorithms dedicated to the estimation of terrestrial evaporation and root-zone soil moisture from satellite data. Ever since its development in 2011, the model has been regularly revised, aiming at the optimal incorporation of new satellite-observed geophysical variables, and improving the representation of physical processes. In this study, the next version of this model (v3) is presented. Key changes relative to the previous version include (1) a revised formulation of the evaporative stress, (2) an optimized drainage algorithm, and (3) a new soil moisture data assimilation system. GLEAM v3 is used to produce three new data sets of terrestrial evaporation and root-zone soil moisture, including a 36-year data set spanning 1980–2015, referred to as v3a (based on satellite-observed soil moisture, vegetation optical depth and snow-water equivalent, reanalysis air temperature and radiation, and a multi-source precipitation product), and two satellite-based data sets. The latter share most of their forcing, except for the vegetation optical depth and soil moisture, which are based on observations from different passive and active C- and L-band microwave sensors (European Space Agency Climate Change Initiative, ESA CCI) for the v3b data set (spanning 2003–2015) and observations from the Soil Moisture and Ocean Salinity (SMOS) satellite in the v3c data set (spanning 2011–2015). Here, these three data sets are described in detail, compared against analogous data sets generated using the previous version of GLEAM (v2), and validated against measurements from 91 eddy-covariance towers and 2325 soil moisture sensors across a broad range of ecosystems. Results indicate that the quality of the v3 soil moisture is consistently better than the one from v2: average correlations against in situ surface soil moisture measurements increase from 0.61 to 0.64 in the case of the v3a data set and the representation of soil moisture in the second layer improves as well, with correlations increasing from 0.47 to 0.53. Similar improvements are observed for the v3b and c data sets. Despite regional differences, the quality of the evaporation fluxes remains overall similar to the one obtained using the previous version of GLEAM, with average correlations against eddy-covariance measurements ranging between 0.78 and 0.81 for the different data sets. These global data sets of terrestrial evaporation and root-zone soil moisture are now openly available at www.GLEAM.eu and may be used for large-scale hydrological applications, climate studies, or research on land–atmosphere feedbacks.

[1]  Martha C. Anderson,et al.  The future of evapotranspiration: Global requirements for ecosystem functioning, carbon and climate feedbacks, agricultural management, and water resources , 2017 .

[2]  Niko E. C. Verhoest,et al.  Assimilation of Global Radar Backscatter and Radiometer Brightness Temperature Observations to Improve Soil Moisture and Land Evaporation Estimates , 2017 .

[3]  J. Norman,et al.  Correcting eddy-covariance flux underestimates over a grassland , 2000 .

[4]  Jian Peng,et al.  High-resolution land surface fluxes from satellite and reanalysis data (HOLAPS v1.0): evaluation and uncertainty assessment , 2016 .

[5]  Niko E. C. Verhoest,et al.  Improving terrestrial evaporation estimates over continental Australia through assimilation of SMOS soil moisture , 2016, Int. J. Appl. Earth Obs. Geoinformation.

[6]  Jaap Schellekens,et al.  MSWEP: 3-hourly 0.25° global gridded precipitation (1979–2015) by merging gauge, satellite, and reanalysis data , 2016 .

[7]  W. Oechel,et al.  Terrestrial carbon balance in a drier world: the effects of water availability in southwestern North America , 2016, Global change biology.

[8]  Wade T. Crow,et al.  Recent advances in (soil moisture) triple collocation analysis , 2016, Int. J. Appl. Earth Obs. Geoinformation.

[9]  Nemesio J. Rodríguez-Fernández,et al.  Global SMOS Soil Moisture Retrievals from The Land Parameter Retrieval Model , 2016, Int. J. Appl. Earth Obs. Geoinformation.

[10]  Marie Combe,et al.  Plant water-stress parameterization determines the strength of land-atmosphere coupling , 2016 .

[11]  Gabrielle De Lannoy,et al.  Global Assimilation of Multiangle and Multipolarization SMOS Brightness Temperature Observations into the GEOS-5 Catchment Land Surface Model for Soil Moisture Estimation , 2016 .

[12]  Yi Y. Liu,et al.  Multi-decadal trends in global terrestrial evapotranspiration and its components , 2016, Scientific Reports.

[13]  M. Mccabe,et al.  Global land evaporation. In: State of the Climate 2015 , 2016 .

[14]  M. Mccabe,et al.  Global land evaporation , 2016 .

[15]  Jian Peng,et al.  High resolution land surface fluxes from satellite data (HOLAPS v1.0): evaluation and uncertainty assessment , 2015 .

[16]  H. Vereecken,et al.  Spatio-temporal drivers of soil and ecosystem carbon fluxes at field scale in an upland grassland in Germany , 2015 .

[17]  Matthew F. McCabe,et al.  The WACMOS-ET project – Part 1: Tower-scale evaluation of four remote-sensing-based evapotranspiration algorithms , 2015 .

[18]  Matthew F. McCabe,et al.  The WACMOS-ET project – Part 2: Evaluation of global terrestrial evaporation data sets , 2015 .

[19]  Ahmad Al Bitar,et al.  SMOS soil moisture assimilation for improved hydrologic simulation in the Murray Darling Basin, Australia , 2015 .

[20]  Matthew F. McCabe,et al.  The GEWEX LandFlux project: evaluation of model evaporation using tower-based and globally gridded forcing data , 2015 .

[21]  Stephen P. Good,et al.  Hydrologic connectivity constrains partitioning of global terrestrial water fluxes , 2015, Science.

[22]  Chun-Hsu Su,et al.  SMOS soil moisture retrievals using the land parameter retrieval model: Evaluation over the Murrumbidgee Catchment, southeast Australia , 2015 .

[23]  W. Wagner,et al.  Evaluation of the ESA CCI soil moisture product using ground-based observations , 2015 .

[24]  Diego G. Miralles,et al.  Reconciling spatial and temporal soil moisture effects on afternoon rainfall , 2015, Nature Communications.

[25]  D. Zona,et al.  Environmental and vegetation controls on the spatial variability of CH4 emission from wet-sedge and tussock tundra ecosystems in the Arctic , 2015, Plant and Soil.

[26]  Stephen P. Good,et al.  Global synthesis of vegetation control on evapotranspiration partitioning , 2014 .

[27]  S. Seneviratne,et al.  Global assessment of trends in wetting and drying over land , 2014 .

[28]  Mao Ning Tuanmu,et al.  A global 1‐km consensus land‐cover product for biodiversity and ecosystem modelling , 2014 .

[29]  A. Dolman,et al.  Fifty years since Monteith's 1965 seminal paper: the emergence of global ecohydrology , 2014 .

[30]  W. Schlesinger,et al.  Transpiration in the global water cycle , 2014 .

[31]  Diego G. Miralles,et al.  Mega-heatwave temperatures due to combined soil desiccation and atmospheric heat accumulation , 2014 .

[32]  Wade T. Crow,et al.  Evaluation of Assumptions in Soil Moisture Triple Collocation Analysis , 2014 .

[33]  N. Verhoest,et al.  El Niño-La Niña cycle and recent trends in continental evaporation , 2014 .

[34]  Matthias Drusch,et al.  Global Automated Quality Control of In Situ Soil Moisture Data from the International Soil Moisture Network , 2013 .

[35]  Yi Y. Liu,et al.  Global vegetation biomass change (1988–2008) and attribution to environmental and human drivers , 2013 .

[36]  Tommaso Julitta,et al.  Phenology and carbon dioxide source/sink strength of a subalpine grassland in response to an exceptionally short snow season , 2013 .

[37]  S. J. Birks,et al.  Terrestrial water fluxes dominated by transpiration , 2013, Nature.

[38]  Wade T. Crow,et al.  The Optimality of Potential Rescaling Approaches in Land Data Assimilation , 2013 .

[39]  L. Barthès,et al.  Distribution of non-structural nitrogen and carbohydrate compounds in mature oak trees in a temperate forest at four key phenological stages , 2013, Trees.

[40]  Matthias J. Zeemana,et al.  Management, not climate, controls net CO2 fluxes and carbon budgets of three grasslands along an elevational gradient in Switzerland , 2013 .

[41]  R.A.M. de Jeu,et al.  Soil moisture‐temperature coupling: A multiscale observational analysis , 2012 .

[42]  B. Law,et al.  Effects of water availability on carbon and water exchange in a young ponderosa pine forest: Above- and belowground responses , 2012 .

[43]  C. Taylor,et al.  Afternoon rain more likely over drier soils , 2012, Nature.

[44]  Yi Y. Liu,et al.  Trend-preserving blending of passive and active microwave soil moisture retrievals , 2012 .

[45]  W. Wagner,et al.  Fusion of active and passive microwave observations to create an Essential Climate Variable data record on soil moisture , 2012 .

[46]  R. Dickinson,et al.  A review of global terrestrial evapotranspiration: Observation, modeling, climatology, and climatic variability , 2011 .

[47]  Yi Y. Liu,et al.  Global long‐term passive microwave satellite‐based retrievals of vegetation optical depth , 2011 .

[48]  A. Robock,et al.  The International Soil Moisture Network: a data hosting facility for global in situ soil moisture measurements , 2011 .

[49]  J. Thepaut,et al.  The ERA‐Interim reanalysis: configuration and performance of the data assimilation system , 2011 .

[50]  W. Crow,et al.  Estimating Spatial Sampling Errors in Coarse-Scale Soil Moisture Estimates Derived from Point-Scale Observations , 2010 .

[51]  T. Holmes,et al.  Global land-surface evaporation estimated from satellite-based observations , 2010 .

[52]  Arnaud Mialon,et al.  SMOS CATDS level 3 global products over land , 2010, Remote Sensing.

[53]  S. Seneviratne,et al.  Contrasting response of European forest and grassland energy exchange to heatwaves , 2010 .

[54]  M. Susan Moran,et al.  Carbon dioxide exchange in a semidesert grassland through drought‐induced vegetation change , 2010 .

[55]  S. Running,et al.  A continuous satellite‐derived global record of land surface evapotranspiration from 1983 to 2006 , 2010 .

[56]  R. Jeu,et al.  Global canopy interception from satellite observations , 2010 .

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

[58]  N. Buchmann,et al.  Management and climate impacts on net CO2 fluxes and carbon budgets of three grasslands along an elevational gradient in Switzerland , 2010 .

[59]  R. Scott Using watershed water balance to evaluate the accuracy of eddy covariance evaporation measurements for three semiarid ecosystems , 2010 .

[60]  T. Holmes,et al.  Global land-surface evaporation , 2010 .

[61]  G. D. Jenerette,et al.  Effects of seasonal drought on net carbon dioxide exchange from a woody-plant-encroached semiarid grassland , 2009 .

[62]  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 .

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

[64]  Jonas Ardö,et al.  Seasonal variation of carbon fluxes in a sparse savanna in semi arid Sudan , 2008, Carbon balance and management.

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

[66]  Ge Sun,et al.  Drought during canopy development has lasting effect on annual carbon balance in a deciduous temperate forest. , 2008, The New phytologist.

[67]  D. Baldocchi,et al.  Global estimates of the land–atmosphere water flux based on monthly AVHRR and ISLSCP-II data, validated at 16 FLUXNET sites , 2008 .

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

[69]  Maosheng Zhao,et al.  Development of a global evapotranspiration algorithm based on MODIS and global meteorology data , 2007 .

[70]  D. Baldocchi,et al.  Inter-annual variability in carbon dioxide exchange of an oak/grass savanna and open grassland in California , 2007 .

[71]  Yong Q. Tian,et al.  Estimating Basal Area and Stem Volume for Individual Trees from Lidar Data , 2007 .

[72]  R. Dickinson,et al.  A numerical approach to calculating soil wetness and evapotranspiration over large grid areas , 2007 .

[73]  Jan Vanderborght,et al.  Measured microwave radiative transfer properties of a deciduous forest canopy , 2007 .

[74]  David P. Billesbach,et al.  Spatiotemporal Variations in Growing Season Exchanges of CO2, H2O, and Sensible Heat in Agricultural Fields of the Southern Great Plains , 2007 .

[75]  Y. Hong,et al.  The TRMM Multisatellite Precipitation Analysis (TMPA): Quasi-Global, Multiyear, Combined-Sensor Precipitation Estimates at Fine Scales , 2007 .

[76]  M. A. Arain,et al.  Carbon dioxide and energy fluxes from a boreal mixedwood forest ecosystem in Ontario, Canada , 2006 .

[77]  Marc Aubinet,et al.  Annual net ecosystem carbon exchange by a sugar beet crop , 2006 .

[78]  Yanhong Tang,et al.  Temperature and biomass influences on interannual changes in CO2 exchange in an alpine meadow on the Qinghai‐Tibetan Plateau , 2006 .

[79]  Pierre Goovaerts,et al.  Fine-resolution mapping of soil organic carbon based on multivariate secondary data , 2006 .

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

[81]  K. Davis,et al.  A multi-site analysis of random error in tower-based measurements of carbon and energy fluxes , 2006 .

[82]  Ruth S. DeFries,et al.  Estimation of tree cover using MODIS data at global, continental and regional/local scales , 2005 .

[83]  Andrew E. Suyker,et al.  Annual carbon dioxide exchange in irrigated and rainfed maize-based agroecosystems , 2005 .

[84]  B. Law,et al.  Forest soil respiration across three climatically distinct chronosequences in Oregon , 2005 .

[85]  M. A. Arain,et al.  Net ecosystem production in a temperate pine plantation in southeastern Canada , 2005 .

[86]  K. Davis,et al.  Carbon exchange and venting anomalies in an upland deciduous forest in northern Wisconsin, USA , 2004 .

[87]  M. Steininger NET CARBON FLUXES FROM FOREST CLEARANCE AND REGROWTH IN THE AMAZON , 2004 .

[88]  B. Law,et al.  Age-related changes in ecosystem structure and function and effects on water and carbon exchange in ponderosa pine. , 2004, Tree physiology.

[89]  Ben Bond-Lamberty,et al.  Net primary production and net ecosystem production of a boreal black spruce wildfire chronosequence , 2004 .

[90]  Jeffrey P. Walker,et al.  THE GLOBAL LAND DATA ASSIMILATION SYSTEM , 2004 .

[91]  R. Leuning,et al.  Evaporation and canopy characteristics of coniferous forests and grasslands , 1993, Oecologia.

[92]  Brigid Amos,et al.  The effect of fertility management on soil surface fluxes of greenhouse gases in an irrigated maize-based agroecosystem , 2005 .

[93]  William L. Smith,et al.  AIRS/AMSU/HSB on the Aqua mission: design, science objectives, data products, and processing systems , 2003, IEEE Trans. Geosci. Remote. Sens..

[94]  W. Oechel,et al.  Energy balance closure at FLUXNET sites , 2002 .

[95]  Olaf Kolle,et al.  Large carbon uptake by an unmanaged 250-year-old deciduous forest in Central Germany , 2002 .

[96]  E. Schulze,et al.  Carbon balance of a southern taiga spruce stand in European Russia , 2002 .

[97]  Albert A. M. Holtslag,et al.  Spatial Heterogeneity of the Soil Moisture Content and Its Impact on Surface Flux Densities and Near-Surface Meteorology , 2002 .

[98]  Richard J. Blakeslee,et al.  Performance Assessment of the Optical Transient Detector and Lightning Imaging Sensor. Part I: Predicted Diurnal Variability , 2002 .

[99]  Philip Marsh,et al.  Surface energy balance of the western and central Canadian subarctic : Variations in the energy balance among five major terrain types , 2001 .

[100]  Yann Kerr,et al.  Soil moisture retrieval from space: the Soil Moisture and Ocean Salinity (SMOS) mission , 2001, IEEE Trans. Geosci. Remote. Sens..

[101]  M. Aubinet,et al.  Long term carbon dioxide exchange above a mixed forest in the Belgian Ardennes , 2001 .

[102]  W. Oechel,et al.  FLUXNET: A New Tool to Study the Temporal and Spatial Variability of Ecosystem-Scale Carbon Dioxide, Water Vapor, and Energy Flux Densities , 2001 .

[103]  Global Soil Data Task,et al.  Global Gridded Surfaces of Selected Soil Characteristics (IGBP-DIS) , 2000 .

[104]  Hans Peter Schmid,et al.  Measurements of CO2 and energy fluxes over a mixed hardwood forest in the mid-western United States , 2000 .

[105]  Ye Qi,et al.  Effects of climate variability on the carbon dioxide, water, and sensible heat fluxes above a ponderosa pine plantation in the Sierra Nevada (CA) , 2000 .

[106]  Hans Peter Schmid,et al.  Measurements of CO 2 and energy fluxes over a mixed hardwood forest in the mid-western United States , 2000 .

[107]  L. H. Allen,et al.  Soybean leaf growth and gas exchange response to drought under carbon dioxide enrichment , 1999 .

[108]  P. Sellers,et al.  Modeling of Energy, Water, and CO2 Flux in a Temperate Grassland Ecosystem with SiB2: May–October 1987 , 1998 .

[109]  F. Valente,et al.  Modelling interception loss for two sparse eucalypt and pine forests in central Portugal using reformulated Rutter and Gash analytical models , 1997 .

[110]  J. William Munger,et al.  Measurements of carbon sequestration by long‐term eddy covariance: methods and a critical evaluation of accuracy , 1996 .

[111]  B. Barkstrom,et al.  Clouds and the Earth's Radiant Energy System (CERES): An Earth Observing System Experiment , 1996 .

[112]  David R. Maidment,et al.  Handbook of Hydrology , 1993 .

[113]  P. Berbigier,et al.  Comparison of two methods for estimating the evaporation of a Pinus pinaster (Ait.) stand: sap flow and energy balance with sensible heat flux measurements by an eddy covariance method , 1991 .

[114]  Y. Viswanadham,et al.  The Priestley-Taylor parameter α for the Amazon forest , 1991 .

[115]  A. Daiwara,et al.  Comparison of two methods for estimating the evaporation of a Pinus pinaster (Ait.) stand : sap flow and energy balance with sensible heat flux measurements by an eddy covariance method , 1991 .

[116]  W. J. Shuttleworth,et al.  Observations of radiation exchange above and below Amazonian forest , 1984 .

[117]  B. Henderson-Sellers,et al.  A new formula for latent heat of vaporization of water as a function of temperature , 1984 .

[118]  W. James Shuttleworth,et al.  Has the Priestley-Taylor Equation Any Relevance to Forest Evaporation? , 1979 .

[119]  J. Gash An analytical model of rainfall interception by forests , 1979 .

[120]  G. Hornberger,et al.  Empirical equations for some soil hydraulic properties , 1978 .

[121]  K. G. McNaughton,et al.  A study of evapotranspiration from a Douglas fir forest using the energy balance approach , 1973 .

[122]  C. Priestley,et al.  On the Assessment of Surface Heat Flux and Evaporation Using Large-Scale Parameters , 1972 .

[123]  R. H. Brooks,et al.  Hydraulic Properties of Porous Media and Their Relation to Drainage Design , 1964 .

[124]  L. A. Richards Capillary conduction of liquids through porous mediums , 1931 .