Dynamic domain kinematic modelling for predicting interflow over leaky impeding layers

Menberu Meles Bitew; C. Rhett Jackson; David C. Goodrich; Seth E. Younger; Natalie A. Griffiths; Kellie B. Vaché; Benjamin Rau

doi:10.1002/hyp.13778

Dynamic domain kinematic modelling for predicting interflow over leaky impeding layers

Menberu Meles Bitew
, C. Rhett Jackson
, David C. Goodrich
, Seth E. Younger
, Natalie A. Griffiths
, Kellie B. Vaché
, Benjamin Rau

Biodiversity and Ecosystem Health

Research output: Contribution to journal › Article › peer-review

9 Scopus citations

Abstract

Traditional Boussinesq or kinematic simulations of interflow (i.e., lateral subsurface flow) assume no leakage through the impeding layer and require a no-flow boundary condition at the ridge top. However, recent analyses of many interflow-producing landscapes indicate that leaky impeding layers are common, that most interflow percolates well before reaching the toe slope, and therefore, the downslope contributing length is shorter than the hillslope length. In watersheds characterised by perched interflow over a low conductivity layer through permeable topsoil, interflow with percolation may be modelled with a kinematic wave model using a mobile upslope boundary condition defining the hillslope portion contributing interflow to valleys. Here, we developed and applied a dynamic interflow model to simulate interflow using a downslope travel distance concept such that only the active contributing length is modelled at any time. The model defines a variable active area based on the depth of the perched layer, the topographic slope and the ratio of the hydraulic conductivity of topsoil to that of the impeding layer. It incorporates a two-layer soil moisture accounting water balance analysis, a pedo-transfer function, and percolation and evaporation routines to predict interflow rates in continuous and event-based scenarios. We tested the modelling concept on two sets of data (2-year dataset of rainfall observations for the continuous simulation and a multi-day irrigation experiment for the event simulation) from a 121-m-long open interflow collection trench on an experimental hillslope at the Savannah River Site, South Carolina. The continuous model simulation partially represented the observed interflow hydrograph and perched water depth in the experimental hillslope with correlation coefficients of 0.85 and 0.35, respectively. Model performance improved significantly at event-scale analysis. The modelling approach realistically represents interflow dynamics in hillslopes with leaky impeding layers and can be integrated into catchment-scale hydrology models for more detailed hillslope process modelling.

Original language	English
Pages (from-to)	2895-2910
Number of pages	16
Journal	Hydrological Processes
Volume	34
Issue number	13
DOIs	https://doi.org/10.1002/hyp.13778
State	Published - Jun 30 2020

Funding

Funding and support were provided by the Department of Energy-Savannah River Operations Office through the U.S. Forest Service Savannah River under Interagency Agreement DE-AI09-00SR22188 and from the U.S. Department of Energy's Bioenergy Technologies Program to Oak Ridge National Laboratory. Oak Ridge National Laboratory is managed by UT-Battelle, LLC, for the U.S. Department of Energy under contract DE-AC05-00OR22725. Department of Energy‐Savannah River Operations Office through the U.S. Forest Service, Grant/Award Number: DE‐AI09‐00SR22188; U.S. Department of Energy's Bioenergy Technologies Program, Grant/Award Number: DE‐AC05‐00OR22725 Funding information Funding and support were provided by the Department of Energy‐Savannah River Operations Office through the U.S. Forest Service Savannah River under Interagency Agreement DE‐AI09‐00SR22188 and from the U.S. Department of Energy's Bioenergy Technologies Program to Oak Ridge National Laboratory. Oak Ridge National Laboratory is managed by UT‐Battelle, LLC, for the U.S. Department of Energy under contract DE‐AC05‐00OR22725. This manuscript has been co‐authored by UT‐Battelle, LLC under Contract No. DE‐AC05‐00OR22725 with the U.S. Department of Energy. The United States Government retains and the publisher, by accepting the article for publication, acknowledges that the United States Government retains a non‐exclusive, paid‐up, irrevocable, worldwide license to publish or reproduce the published form of this manuscript, or allow others to do so, for United States Government purposes. The Department of Energy will provide public access to these results of federally sponsored research in accordance with the DOE Public Access Plan ( http://energy.gov/downloads/doe-public-access-plan ).

Keywords

Boussinesq
downslope travel distance
hillslope
interflow modelling
kinematic
leaky impeding layer
open trench

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10.1002/hyp.13778

Cite this

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title = "Dynamic domain kinematic modelling for predicting interflow over leaky impeding layers",

abstract = "Traditional Boussinesq or kinematic simulations of interflow (i.e., lateral subsurface flow) assume no leakage through the impeding layer and require a no-flow boundary condition at the ridge top. However, recent analyses of many interflow-producing landscapes indicate that leaky impeding layers are common, that most interflow percolates well before reaching the toe slope, and therefore, the downslope contributing length is shorter than the hillslope length. In watersheds characterised by perched interflow over a low conductivity layer through permeable topsoil, interflow with percolation may be modelled with a kinematic wave model using a mobile upslope boundary condition defining the hillslope portion contributing interflow to valleys. Here, we developed and applied a dynamic interflow model to simulate interflow using a downslope travel distance concept such that only the active contributing length is modelled at any time. The model defines a variable active area based on the depth of the perched layer, the topographic slope and the ratio of the hydraulic conductivity of topsoil to that of the impeding layer. It incorporates a two-layer soil moisture accounting water balance analysis, a pedo-transfer function, and percolation and evaporation routines to predict interflow rates in continuous and event-based scenarios. We tested the modelling concept on two sets of data (2-year dataset of rainfall observations for the continuous simulation and a multi-day irrigation experiment for the event simulation) from a 121-m-long open interflow collection trench on an experimental hillslope at the Savannah River Site, South Carolina. The continuous model simulation partially represented the observed interflow hydrograph and perched water depth in the experimental hillslope with correlation coefficients of 0.85 and 0.35, respectively. Model performance improved significantly at event-scale analysis. The modelling approach realistically represents interflow dynamics in hillslopes with leaky impeding layers and can be integrated into catchment-scale hydrology models for more detailed hillslope process modelling.",

keywords = "Boussinesq, downslope travel distance, hillslope, interflow modelling, kinematic, leaky impeding layer, open trench",

author = "\{Meles Bitew\}, Menberu and Jackson, \{C. Rhett\} and Goodrich, \{David C.\} and Younger, \{Seth E.\} and Griffiths, \{Natalie A.\} and Vach{\'e}, \{Kellie B.\} and Benjamin Rau",

note = "Publisher Copyright: Published 2020. This article is a U.S. Government work and is in the public domain in the USA",

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T1 - Dynamic domain kinematic modelling for predicting interflow over leaky impeding layers

AU - Meles Bitew, Menberu

AU - Jackson, C. Rhett

AU - Goodrich, David C.

AU - Younger, Seth E.

AU - Griffiths, Natalie A.

AU - Vaché, Kellie B.

AU - Rau, Benjamin

N1 - Publisher Copyright: Published 2020. This article is a U.S. Government work and is in the public domain in the USA

PY - 2020/6/30

Y1 - 2020/6/30

N2 - Traditional Boussinesq or kinematic simulations of interflow (i.e., lateral subsurface flow) assume no leakage through the impeding layer and require a no-flow boundary condition at the ridge top. However, recent analyses of many interflow-producing landscapes indicate that leaky impeding layers are common, that most interflow percolates well before reaching the toe slope, and therefore, the downslope contributing length is shorter than the hillslope length. In watersheds characterised by perched interflow over a low conductivity layer through permeable topsoil, interflow with percolation may be modelled with a kinematic wave model using a mobile upslope boundary condition defining the hillslope portion contributing interflow to valleys. Here, we developed and applied a dynamic interflow model to simulate interflow using a downslope travel distance concept such that only the active contributing length is modelled at any time. The model defines a variable active area based on the depth of the perched layer, the topographic slope and the ratio of the hydraulic conductivity of topsoil to that of the impeding layer. It incorporates a two-layer soil moisture accounting water balance analysis, a pedo-transfer function, and percolation and evaporation routines to predict interflow rates in continuous and event-based scenarios. We tested the modelling concept on two sets of data (2-year dataset of rainfall observations for the continuous simulation and a multi-day irrigation experiment for the event simulation) from a 121-m-long open interflow collection trench on an experimental hillslope at the Savannah River Site, South Carolina. The continuous model simulation partially represented the observed interflow hydrograph and perched water depth in the experimental hillslope with correlation coefficients of 0.85 and 0.35, respectively. Model performance improved significantly at event-scale analysis. The modelling approach realistically represents interflow dynamics in hillslopes with leaky impeding layers and can be integrated into catchment-scale hydrology models for more detailed hillslope process modelling.

AB - Traditional Boussinesq or kinematic simulations of interflow (i.e., lateral subsurface flow) assume no leakage through the impeding layer and require a no-flow boundary condition at the ridge top. However, recent analyses of many interflow-producing landscapes indicate that leaky impeding layers are common, that most interflow percolates well before reaching the toe slope, and therefore, the downslope contributing length is shorter than the hillslope length. In watersheds characterised by perched interflow over a low conductivity layer through permeable topsoil, interflow with percolation may be modelled with a kinematic wave model using a mobile upslope boundary condition defining the hillslope portion contributing interflow to valleys. Here, we developed and applied a dynamic interflow model to simulate interflow using a downslope travel distance concept such that only the active contributing length is modelled at any time. The model defines a variable active area based on the depth of the perched layer, the topographic slope and the ratio of the hydraulic conductivity of topsoil to that of the impeding layer. It incorporates a two-layer soil moisture accounting water balance analysis, a pedo-transfer function, and percolation and evaporation routines to predict interflow rates in continuous and event-based scenarios. We tested the modelling concept on two sets of data (2-year dataset of rainfall observations for the continuous simulation and a multi-day irrigation experiment for the event simulation) from a 121-m-long open interflow collection trench on an experimental hillslope at the Savannah River Site, South Carolina. The continuous model simulation partially represented the observed interflow hydrograph and perched water depth in the experimental hillslope with correlation coefficients of 0.85 and 0.35, respectively. Model performance improved significantly at event-scale analysis. The modelling approach realistically represents interflow dynamics in hillslopes with leaky impeding layers and can be integrated into catchment-scale hydrology models for more detailed hillslope process modelling.

KW - Boussinesq

KW - downslope travel distance

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KW - interflow modelling

KW - kinematic

KW - leaky impeding layer

KW - open trench

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DO - 10.1002/hyp.13778

M3 - Article

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SN - 0885-6087

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EP - 2910

JO - Hydrological Processes

JF - Hydrological Processes

IS - 13

ER -

Dynamic domain kinematic modelling for predicting interflow over leaky impeding layers

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