A Subgrid Approach for Modeling Microtopography Effects on Overland Flow

Ahmad Jan; Ethan T. Coon; Jake D. Graham; Scott L. Painter

doi:10.1029/2017WR021898

A Subgrid Approach for Modeling Microtopography Effects on Overland Flow

Ahmad Jan, Ethan T. Coon, Jake D. Graham, Scott L. Painter

Watershed Systems Modeling

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

23 Scopus citations

Abstract

Microtopography, or heterogeneities in the elevation across scales much smaller than the domain of interest, plays a critical role in surface water retention, surface/subsurface interactions, and runoff. Resolving microtopographic influences on flow requires high-resolution simulations that are computationally demanding even when considering the surface system in isolation and even more so when surface flow is one component in integrated simulations that couple surface flow with unsaturated subsurface flow. There is thus significant motivation for models that allow the effects of subgrid microtopography to be better represented. Subgrid models modify coarsened models to capture the microtopography-induced nonlinear effects on hydrologic processes. We present a subgrid model that alters the water storage and flow terms in the diffusion wave equation for surface flow. Stochastically generated microtopography with strongly contrasting spatial structure, high-resolution digital elevation maps from a polygonal tundra site on the North Slope of Alaska and a hummocky microtopography from a field site in Northern Minnesota are used to assess the accuracy and applicability of the subgrid model to disparate landscapes. Approaches for determining subgrid model parameters are tested and simulation results using the subgrid model are compared to benchmark fine-scale simulations and to coarse simulations that ignore microtopography. Our findings confirm that a properly parameterized subgrid model greatly improves the coarse-scale representation of hydrographs and total water content in the system. Using the polygonal tundra example, we propose and test a strategy for moving to application-relevant spatial scales by combining microtopography classification and a few fine-scale simulations on small subdomains.

Original language	English
Pages (from-to)	6153-6167
Number of pages	15
Journal	Water Resources Research
Volume	54
Issue number	9
DOIs	https://doi.org/10.1029/2017WR021898
State	Published - Sep 2018

Funding

Received 19 SEP 2017 Accepted 25 JUL 2018 Accepted article online 2 AUG 2018 Published online 10 SEP 2018 ©2018. American Geophysical Union. All Rights Reserved. This manuscript has been authored by UT-Battelle, LLC under contract DE-AC05-00OR22725 with the U.S. Department of Energy. The U.S. Government retains and the publisher, by accepting the article for publication, acknowledges that the United States Government retains a nonexclusive, paid-up, irrevocable, worldwide license to publish or reproduce the published form of this manuscript, or allow others to do so, for U.S. 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). This work was supported by Interoperable Design of Extreme-scale Application Software (IDEAS) project and by the Next-Generation Ecosystem Experiment?Arctic (NGEE-Arctic) project. Jake Graham was supported under a contract between Oak Ridge National Laboratory and Boise State University (4000145196) with funding for the SPRUCE project. The IDEAS, NGEE-Arctic, and SPRUCE projects are supported by the Office of Biological and Environmental Research in the U.S. Department of Energy's Office of Science. Oak Ridge National Laboratory is managed by UT-Battelle, LLC, for DOE under contract DE-AC05-00OR22725. We are also grateful to Jitu Kumar and Terry Miller for help in constructing computational meshes. Data can be accessed at https://doi.org/10.5440/1416559. This work was supported by Interoperable Design of Extreme-scale Application Software (IDEAS) project and by the Next-Generation Ecosystem Experiment—Arctic (NGEE-Arctic) project. Jake Graham was supported under a contract between Oak Ridge National Laboratory and Boise State University (4000145196) with funding for the SPRUCE project. The IDEAS, NGEE-Arctic, and SPRUCE projects are supported by the Office of Biological and Environmental Research in the U.S. Department of Energy’s Office of Science. Oak Ridge National Laboratory is managed by UT-Battelle, LLC, for DOE under contract DE-AC05-00OR22725. We are also grateful to Jitu Kumar and Terry Miller for help in constructing computational meshes. Data can be accessed at https://doi.org/10.5440/ 1416559.

Keywords

catchment
microtopography
subgrid model
surface flow

Access to Document

10.1029/2017WR021898

Cite this

@article{b1fe4bb6a0ea46de86b13288e8a73dcf,

title = "A Subgrid Approach for Modeling Microtopography Effects on Overland Flow",

abstract = "Microtopography, or heterogeneities in the elevation across scales much smaller than the domain of interest, plays a critical role in surface water retention, surface/subsurface interactions, and runoff. Resolving microtopographic influences on flow requires high-resolution simulations that are computationally demanding even when considering the surface system in isolation and even more so when surface flow is one component in integrated simulations that couple surface flow with unsaturated subsurface flow. There is thus significant motivation for models that allow the effects of subgrid microtopography to be better represented. Subgrid models modify coarsened models to capture the microtopography-induced nonlinear effects on hydrologic processes. We present a subgrid model that alters the water storage and flow terms in the diffusion wave equation for surface flow. Stochastically generated microtopography with strongly contrasting spatial structure, high-resolution digital elevation maps from a polygonal tundra site on the North Slope of Alaska and a hummocky microtopography from a field site in Northern Minnesota are used to assess the accuracy and applicability of the subgrid model to disparate landscapes. Approaches for determining subgrid model parameters are tested and simulation results using the subgrid model are compared to benchmark fine-scale simulations and to coarse simulations that ignore microtopography. Our findings confirm that a properly parameterized subgrid model greatly improves the coarse-scale representation of hydrographs and total water content in the system. Using the polygonal tundra example, we propose and test a strategy for moving to application-relevant spatial scales by combining microtopography classification and a few fine-scale simulations on small subdomains.",

keywords = "catchment, microtopography, subgrid model, surface flow",

author = "Ahmad Jan and Coon, {Ethan T.} and Graham, {Jake D.} and Painter, {Scott L.}",

year = "2018",

month = sep,

doi = "10.1029/2017WR021898",

language = "English",

volume = "54",

pages = "6153--6167",

journal = "Water Resources Research",

issn = "0043-1397",

publisher = "Wiley Open Access",

number = "9",

}

TY - JOUR

T1 - A Subgrid Approach for Modeling Microtopography Effects on Overland Flow

AU - Jan, Ahmad

AU - Coon, Ethan T.

AU - Graham, Jake D.

AU - Painter, Scott L.

PY - 2018/9

Y1 - 2018/9

N2 - Microtopography, or heterogeneities in the elevation across scales much smaller than the domain of interest, plays a critical role in surface water retention, surface/subsurface interactions, and runoff. Resolving microtopographic influences on flow requires high-resolution simulations that are computationally demanding even when considering the surface system in isolation and even more so when surface flow is one component in integrated simulations that couple surface flow with unsaturated subsurface flow. There is thus significant motivation for models that allow the effects of subgrid microtopography to be better represented. Subgrid models modify coarsened models to capture the microtopography-induced nonlinear effects on hydrologic processes. We present a subgrid model that alters the water storage and flow terms in the diffusion wave equation for surface flow. Stochastically generated microtopography with strongly contrasting spatial structure, high-resolution digital elevation maps from a polygonal tundra site on the North Slope of Alaska and a hummocky microtopography from a field site in Northern Minnesota are used to assess the accuracy and applicability of the subgrid model to disparate landscapes. Approaches for determining subgrid model parameters are tested and simulation results using the subgrid model are compared to benchmark fine-scale simulations and to coarse simulations that ignore microtopography. Our findings confirm that a properly parameterized subgrid model greatly improves the coarse-scale representation of hydrographs and total water content in the system. Using the polygonal tundra example, we propose and test a strategy for moving to application-relevant spatial scales by combining microtopography classification and a few fine-scale simulations on small subdomains.

AB - Microtopography, or heterogeneities in the elevation across scales much smaller than the domain of interest, plays a critical role in surface water retention, surface/subsurface interactions, and runoff. Resolving microtopographic influences on flow requires high-resolution simulations that are computationally demanding even when considering the surface system in isolation and even more so when surface flow is one component in integrated simulations that couple surface flow with unsaturated subsurface flow. There is thus significant motivation for models that allow the effects of subgrid microtopography to be better represented. Subgrid models modify coarsened models to capture the microtopography-induced nonlinear effects on hydrologic processes. We present a subgrid model that alters the water storage and flow terms in the diffusion wave equation for surface flow. Stochastically generated microtopography with strongly contrasting spatial structure, high-resolution digital elevation maps from a polygonal tundra site on the North Slope of Alaska and a hummocky microtopography from a field site in Northern Minnesota are used to assess the accuracy and applicability of the subgrid model to disparate landscapes. Approaches for determining subgrid model parameters are tested and simulation results using the subgrid model are compared to benchmark fine-scale simulations and to coarse simulations that ignore microtopography. Our findings confirm that a properly parameterized subgrid model greatly improves the coarse-scale representation of hydrographs and total water content in the system. Using the polygonal tundra example, we propose and test a strategy for moving to application-relevant spatial scales by combining microtopography classification and a few fine-scale simulations on small subdomains.

KW - catchment

KW - microtopography

KW - subgrid model

KW - surface flow

UR - http://www.scopus.com/inward/record.url?scp=85053031837&partnerID=8YFLogxK

U2 - 10.1029/2017WR021898

DO - 10.1029/2017WR021898

M3 - Article

AN - SCOPUS:85053031837

SN - 0043-1397

VL - 54

SP - 6153

EP - 6167

JO - Water Resources Research

JF - Water Resources Research

IS - 9

ER -

A Subgrid Approach for Modeling Microtopography Effects on Overland Flow

Abstract

Funding

Keywords

Access to Document

Other files and links

Fingerprint