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References (21)
-
J. Robinson, M. Sivapalan (1997)
Temporal scales and hydrological regimes: Implications for flood frequency scalingWater Resources Research, 33
-
S. Hassanizadeh, W. Gray (1990)
Mechanics and thermodynamics of multiphase flow in porous media including interphase boundariesAdvances in Water Resources, 13
-
P. Eagleson (1978)
Climate, soil, and vegetation: 7. A derived distribution of annual water yieldWater Resources Research, 14
-
P. Reggiani, M. Sivapalan, S. Hassanizadeh (1998)
A unifying framework for watershed thermodynamics: balance equations for mass, momentum, energy and entropy, and the second law of thermodynamicsAdvances in Water Resources, 22
-
Burdine Burdine (1958)
Relative permeability calculations from pore size distribution dataTrans. Am. Inst. Min. Metall. Pet. Eng., 198
-
C. Duffy (1996)
A TWO-STATE INTEGRAL-BALANCE MODEL FOR SOIL MOISTURE AND GROUNDWATER DYNAMICS IN COMPLEX TERRAINWater Resources Research, 32
-
W. Press, S. Teukolsky, W. Vetterling, B. Flannery (2002)
Numerical recipes in C -
(1999)
Coupled equations for mass and momentum balance in a bifurcating stream channel network: Theoretical derivation and numerical implementation, Reoe. ED 1266 PR, Cent. for Water Res -
P. Milly (1994)
Climate, soil water storage, and the average annual water balanceWater Resources Research, 30
-
R. Brooks, A. Corey (1966)
Properties of Porous Media Affecting Fluid FlowJournal of the Irrigation and Drainage Division, 92
-
P. Reggiani, S. Hassanizadeh, M. Sivapalan, W. Gray (1999)
A unifying framework for watershed thermodynamics: constitutive relationshipsAdvances in Water Resources, 23
-
B. Coleman, W. Noll (1963)
The thermodynamics of elastic materials with heat conduction and viscosityArchive for Rational Mechanics and Analysis, 13
-
K. Hawk, P. Eagleson (1992)
Climatology of Station Storm Rainfall in the Continental United States: Parameters of the Bartlett-Lewis and Poisson Rectangular Pulses Models -
R. Bras (1990)
Hydrology : an introduction to hydrologic science -
G. Salvucci, D. Entekhabi (1994)
Comparison of the Eagleson statistical-dynamical water balance model with numerical simulationsWater Resources Research, 30
-
P. Eagleson (1978)
Climate, soil, and vegetation: 1. Introduction to water balance dynamicsWater Resources Research, 14
-
N. Burdine (1953)
Relative Permeability Calculations From Pore Size Distribution DataJournal of Petroleum Technology, 5
-
G. Salvucci, D. Entekhabi (1995)
Hillslope and Climatic Controls on Hydrologic FluxesWater Resources Research, 31
-
P. Eagleson (1978)
Climate, soil, and vegetation: 6. Dynamics of the annual water balanceWater Resources Research, 14
-
P. Eagleson (1978)
Climate, soil, and vegetation: 4. The expected value of annual evapotranspirationWater Resources Research, 14
-
Field studies of hillslope flow processes
- Publisher
- Wiley
- Copyright
- Copyright © 2000 by the American Geophysical Union.
- ISSN
- 0043-1397
- eISSN
- 1944-7973
- DOI
- 10.1029/2000WR900066
- Publisher site
- See Article on Publisher Site
Abstract
A unifying approach for the derivation of watershed‐scale conservation equations governing hydrologic responses has recently been introduced. The approach is based on space‐time averaging of the corresponding point‐scale conservation equations over an averaging region called the representative elementary watershed (REW). The conservation equations are supplemented by constitutive relationships needed for the closure of various mass and momentum exchange terms. In this paper, we present a summary of the resulting equations for a somewhat simpler problem and show how these equations can be employed to model the long‐term water balance of a single, hypothetical REW. The governing equations are formulated in terms of an average saturation and a flow velocity of the unsaturated zone soils and the average thickness of the saturated zone soils. The equations are coupled ordinary differential equations and are nonlinear. Their solution is carried out simultaneously for a variety of combinations of watershed geometry, soil type, and atmospheric forcing. We show how a similarity analysis of the governing equations can lead to a general classification of REWs in terms of meaningful dimensionless similarity variables. In addition, we investigate the long‐term water balance and show that the governing equations are able to provide a realistic picture of the impact of changing climate, soil, and topographic controls on long‐term water balance.
Journal
Water Resources Research – Wiley
Published: Jul 1, 2000