Operational Evapotranspiration Mapping Using Remote Sensing and Weather Datasets: A New Parameterization for the SSEB Approach

Operational Evapotranspiration Mapping Using Remote Sensing and Weather Datasets: A New Parameterization for the SSEB Approach

The increasing availability of multi‐scale remotely sensed data and global weather datasets is allowing the estimation of evapotranspiration (ET) at multiple scales. We present a simple but robust method that uses remotely sensed thermal data and model‐assimilated weather fields to produce ET for th...

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Bibliographic Details
Published in:Journal of the American Water Resources Association Vol. 49; no. 3; pp. 577 - 591
Main Authors: Senay, Gabriel B., Bohms, Stefanie, Singh, Ramesh K., Gowda, Prasanna H., Velpuri, Naga M., Alemu, Henok, Verdin, James P.
Format: Journal Article
Language:English
Published: Middleburg Blackwell Publishing Ltd 01-06-2013
Subjects:
Boundary conditions
Climatology
Data assimilation
Drought
Droughts
Evapotranspiration
irrigation
Marine
Mathematical models
Parametrization
Remote sensing
Sensors
Water supply
water use
Weather
USA
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Summary:The increasing availability of multi‐scale remotely sensed data and global weather datasets is allowing the estimation of evapotranspiration (ET) at multiple scales. We present a simple but robust method that uses remotely sensed thermal data and model‐assimilated weather fields to produce ET for the contiguous United States (CONUS) at monthly and seasonal time scales. The method is based on the Simplified Surface Energy Balance (SSEB) model, which is now parameterized for operational applications, renamed as SSEBop. The innovative aspect of the SSEBop is that it uses predefined boundary conditions that are unique to each pixel for the “hot” and “cold” reference conditions. The SSEBop model was used for computing ET for 12 years (2000‐2011) using the MODIS and Global Data Assimilation System (GDAS) data streams. SSEBop ET results compared reasonably well with monthly eddy covariance ET data explaining 64% of the observed variability across diverse ecosystems in the CONUS during 2005. Twelve annual ET anomalies (2000‐2011) depicted the spatial extent and severity of the commonly known drought years in the CONUS. More research is required to improve the representation of the predefined boundary conditions in complex terrain at small spatial scales. SSEBop model was found to be a promising approach to conduct water use studies in the CONUS, with a similar opportunity in other parts of the world. The approach can also be applied with other thermal sensors such as Landsat.
Bibliography:WaterSMART project
istex:313B42CAD1DDD6F1E67D0F94F2379DEBC11F1C76
ark:/67375/WNG-K7N0FT60-L
Paper No. JAWRA-12-0097-P of the Journal of the American Water Resources Association (JAWRA).
ArticleID:JAWR12057
ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 23
ISSN:1093-474X
1752-1688
DOI:10.1111/jawr.12057