Implications of GRACE Satellite Gravity Measurements for Diverse Hydrological Applications

Soil moisture plays a major role in the hydrologic water balance and is the basis for most hydrological models. It influences the partitioning of energy and moisture inputs at the land surface. Because of its importance, it has been used as a key variable for many hydrological studies such as flood...

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Bibliographic Details
Main Author: Yirdaw-Zeleke, Sitotaw
Other Authors: Snelgrove, Kenneth (Civil Engineering), Woodbury, Allan (Civil Engineering) Rasmussen, Peter (Civil Engineering) Hanesiak, John (Environment & Geography) Hayashi, Masaki (Department of Geoscience, University of Calgary)
Format: Doctoral or Postdoctoral Thesis
Language:English
Published: 2010
Subjects:
GRACE Satellite
Total Water Storage
Mackenzie River Basin
Canadian Prairie
Drought
TSDI
Water Balance
Cold Region
ADA
Coupled Hydrological Model
Mackenzie River
Mackenzie river
Online Access:http://hdl.handle.net/1993/3944
Description
Summary:Soil moisture plays a major role in the hydrologic water balance and is the basis for most hydrological models. It influences the partitioning of energy and moisture inputs at the land surface. Because of its importance, it has been used as a key variable for many hydrological studies such as flood forecasting, drought studies and the determination of groundwater recharge. Therefore, spatially distributed soil moisture with reasonable temporal resolution is considered a valuable source of information for hydrological model parameterization and validation. Unfortunately, soil moisture is difficult to measure and remains essentially unmeasured over spatial and temporal scales needed for a number of hydrological model applications. In 2002, the Gravity Recovery And Climate Experiment (GRACE) satellite platform was launched to measure, among other things, the gravitational field of the earth. Over its life span, these orbiting satellites have produced time series of mass changes of the earth-atmosphere system. The subsequent outcome of this, after integration over a number of years, is a time series of highly refined images of the earth's mass distribution. In addition to quantifying the static distribution of mass, the month-to-month variation in the earth's gravitational field are indicative of the integrated value of the subsurface total water storage for specific catchments. Utilization of these natural changes in the earth's gravitational field entails the transformation of the derived GRACE geopotential spherical harmonic coefficients into spatially varying time series estimates of total water storage. These remotely sensed basin total water storage estimates can be routinely validated against independent estimates of total water storage from an atmospheric-based water balance approach or from well calibrated macroscale hydrologic models. The hydrological relevance and implications of remotely estimated GRACE total water storage over poorly gauged, wetland-dominated watershed as well as over a deltaic region ...

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