Coupled surface-subsurface flow model for improved basin irrigation management

TY - JOUR

T1 - Coupled surface-subsurface flow model for improved basin irrigation management

AU - Zerihun, D.

AU - Furman, A.

AU - Warrick, A. W.

AU - Sanchez, C. A.

PY - 2005/3

Y1 - 2005/3

N2 - The availability of a process-based coupled surface-subsurface model can lead to improved surface irrigation/fertigation management practices. In this study, a one-dimensional zero-inertia model is coupled with a one-dimensional unsaturated zone water-flow model: HYDRUS-1D. A driver program is used to effect internal iterative coupling of the surface and subsurface flow models. Flow depths calculated using the surface-flow model are used as Dirichlet boundary conditions for the subsurface-flow model, and infiltration amounts calculated by the subsurface model are in turn used in surface-flow mass balance calculations. The model was tested by using field data collected at the University of Arizona, Yuma Mesa, research farm. The maximum mean absolute difference between field-observed and model-predicted advance is 2 min. Applications of the coupled model in improved irrigation management are highlighted. In addition, the significance of the effects of soil moisture redistribution on irrigation water availability to crops and the capability of the coupled model in tracking those changes in soil water status over time are discussed using examples.

AB - The availability of a process-based coupled surface-subsurface model can lead to improved surface irrigation/fertigation management practices. In this study, a one-dimensional zero-inertia model is coupled with a one-dimensional unsaturated zone water-flow model: HYDRUS-1D. A driver program is used to effect internal iterative coupling of the surface and subsurface flow models. Flow depths calculated using the surface-flow model are used as Dirichlet boundary conditions for the subsurface-flow model, and infiltration amounts calculated by the subsurface model are in turn used in surface-flow mass balance calculations. The model was tested by using field data collected at the University of Arizona, Yuma Mesa, research farm. The maximum mean absolute difference between field-observed and model-predicted advance is 2 min. Applications of the coupled model in improved irrigation management are highlighted. In addition, the significance of the effects of soil moisture redistribution on irrigation water availability to crops and the capability of the coupled model in tracking those changes in soil water status over time are discussed using examples.

KW - Coupling

KW - Hydrologic models

KW - Irrigation practices

KW - Surface irrigation

KW - Unsaturated flow

UR - http://www.scopus.com/inward/record.url?scp=16344361935&partnerID=8YFLogxK

U2 - 10.1061/(ASCE)0733-9437(2005)131:2(111)

DO - 10.1061/(ASCE)0733-9437(2005)131:2(111)

M3 - 文章

AN - SCOPUS:16344361935

SN - 0733-9437

VL - 131

SP - 111

EP - 128

JO - Journal of Irrigation and Drainage Engineering - ASCE

JF - Journal of Irrigation and Drainage Engineering - ASCE

IS - 2

ER -