Global root zone storage capacity from satellite-based evaporation

Global root zone storage capacity from satellite-based evaporation

This study presents an "Earth observation-based" method for estimating root zone storage capacity – a critical, yet uncertain parameter in hydrological and land surface modelling. By assuming that vegetation optimises its root zone storage capacity to bridge critical dry periods, we were a...

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Bibliographic Details
Published in:Hydrology and earth system sciences Vol. 20; no. 4; pp. 1459 - 1481
Main Authors: Wang-Erlandsson, Lan, Bastiaanssen, Wim G. M, Gao, Hongkai, Jägermeyr, Jonas, Senay, Gabriel B, van Dijk, Albert I. J. M, Guerschman, Juan P, Keys, Patrick W, Gordon, Line J, Savenije, Hubert H. G
Format: Journal Article
Language:English
Published: Katlenburg-Lindau Copernicus GmbH 19-04-2016
Copernicus Publications
Subjects:
Adaptation
Agricultural land
Atmospheric models
Bridges
Calibration
Carbon
Computer simulation
Drought
Dry periods
Earth
Earth observations (from space)
Energy balance
Energy storage
Evaporation
Evaporation data
Grasslands
Groundwater
Hydrologic models
Hydrology
Irrigation
Land cover
Lookup tables
Mathematical models
Methods
Modelling
Parameter uncertainty
Precipitation
Rainforests
Remote sensing
Root zone
Rooting
Satellites
Savannahs
Seasonal variations
Seasonality
Soil
Soils
Storage capacity
Storage conditions
Vegetation
United States > US
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Summary:This study presents an "Earth observation-based" method for estimating root zone storage capacity – a critical, yet uncertain parameter in hydrological and land surface modelling. By assuming that vegetation optimises its root zone storage capacity to bridge critical dry periods, we were able to use state-of-the-art satellite-based evaporation data computed with independent energy balance equations to derive gridded root zone storage capacity at global scale. This approach does not require soil or vegetation information, is model independent, and is in principle scale independent. In contrast to a traditional look-up table approach, our method captures the variability in root zone storage capacity within land cover types, including in rainforests where direct measurements of root depths otherwise are scarce. Implementing the estimated root zone storage capacity in the global hydrological model STEAM (Simple Terrestrial Evaporation to Atmosphere Model) improved evaporation simulation overall, and in particular during the least evaporating months in sub-humid to humid regions with moderate to high seasonality. Our results suggest that several forest types are able to create a large storage to buffer for severe droughts (with a very long return period), in contrast to, for example, savannahs and woody savannahs (medium length return period), as well as grasslands, shrublands, and croplands (very short return period). The presented method to estimate root zone storage capacity eliminates the need for poor resolution soil and rooting depth data that form a limitation for achieving progress in the global land surface modelling community.
ISSN:1607-7938
1027-5606
1607-7938
DOI:10.5194/hess-20-1459-2016