Mass-Conserving Downscaling of Climate Model Precipitation Over Mountainous Terrain for Water Resource Applications

A. Rugg; E. D. Gutmann; R. R. McCrary; F. Lehner; A. J. Newman; J. H. Richter; M. R. Tye; A. W. Wood

doi:10.1029/2023GL105326

Mass-Conserving Downscaling of Climate Model Precipitation Over Mountainous Terrain for Water Resource Applications

A. Rugg, E. D. Gutmann, R. R. McCrary, F. Lehner, A. J. Newman, J. H. Richter, M. R. Tye, A. W. Wood

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1 Scopus citations

Abstract

A mass-conserving method to downscale precipitation from global climate models (GCMs) using sub-grid-scale topography and modeled 700-mb wind direction is presented. Runoff is simulated using a stand-alone hydrological model, with this and several other methods as inputs, and compared to runoff simulated using historical observations over the western contiguous United States. Results suggest the mitigation of grid-scale biases is more critical than downscaling for some regions with large wet biases (e.g., the Great Basin and Upper Colorado). In other regions (e.g., the Pacific Northwest) the new method produces more realistic sub-grid-scale variability in runoff compared to unadjusted GCM output and a simpler downscaling method. The presented method also brings the runoff centroid timing closer to that simulated with observations for all subregions examined.

Original language	English
Article number	e2023GL105326
Journal	Geophysical Research Letters
Volume	50
Issue number	20
DOIs	https://doi.org/10.1029/2023GL105326
State	Published - Oct 28 2023
Externally published	Yes

Keywords

climate change
downscaling
hydrological modeling
mountainous terrain
water resources
western United States

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10.1029/2023GL105326

Cite this

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title = "Mass-Conserving Downscaling of Climate Model Precipitation Over Mountainous Terrain for Water Resource Applications",

abstract = "A mass-conserving method to downscale precipitation from global climate models (GCMs) using sub-grid-scale topography and modeled 700-mb wind direction is presented. Runoff is simulated using a stand-alone hydrological model, with this and several other methods as inputs, and compared to runoff simulated using historical observations over the western contiguous United States. Results suggest the mitigation of grid-scale biases is more critical than downscaling for some regions with large wet biases (e.g., the Great Basin and Upper Colorado). In other regions (e.g., the Pacific Northwest) the new method produces more realistic sub-grid-scale variability in runoff compared to unadjusted GCM output and a simpler downscaling method. The presented method also brings the runoff centroid timing closer to that simulated with observations for all subregions examined.",

keywords = "climate change, downscaling, hydrological modeling, mountainous terrain, water resources, western United States",

author = "A. Rugg and Gutmann, \{E. D.\} and McCrary, \{R. R.\} and F. Lehner and Newman, \{A. J.\} and Richter, \{J. H.\} and Tye, \{M. R.\} and Wood, \{A. W.\}",

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year = "2023",

month = oct,

day = "28",

doi = "10.1029/2023GL105326",

language = "English",

volume = "50",

journal = "Geophysical Research Letters",

issn = "0094-8276",

publisher = "John Wiley and Sons Inc.",

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TY - JOUR

T1 - Mass-Conserving Downscaling of Climate Model Precipitation Over Mountainous Terrain for Water Resource Applications

AU - Rugg, A.

AU - Gutmann, E. D.

AU - McCrary, R. R.

AU - Lehner, F.

AU - Newman, A. J.

AU - Richter, J. H.

AU - Tye, M. R.

AU - Wood, A. W.

PY - 2023/10/28

Y1 - 2023/10/28

N2 - A mass-conserving method to downscale precipitation from global climate models (GCMs) using sub-grid-scale topography and modeled 700-mb wind direction is presented. Runoff is simulated using a stand-alone hydrological model, with this and several other methods as inputs, and compared to runoff simulated using historical observations over the western contiguous United States. Results suggest the mitigation of grid-scale biases is more critical than downscaling for some regions with large wet biases (e.g., the Great Basin and Upper Colorado). In other regions (e.g., the Pacific Northwest) the new method produces more realistic sub-grid-scale variability in runoff compared to unadjusted GCM output and a simpler downscaling method. The presented method also brings the runoff centroid timing closer to that simulated with observations for all subregions examined.

AB - A mass-conserving method to downscale precipitation from global climate models (GCMs) using sub-grid-scale topography and modeled 700-mb wind direction is presented. Runoff is simulated using a stand-alone hydrological model, with this and several other methods as inputs, and compared to runoff simulated using historical observations over the western contiguous United States. Results suggest the mitigation of grid-scale biases is more critical than downscaling for some regions with large wet biases (e.g., the Great Basin and Upper Colorado). In other regions (e.g., the Pacific Northwest) the new method produces more realistic sub-grid-scale variability in runoff compared to unadjusted GCM output and a simpler downscaling method. The presented method also brings the runoff centroid timing closer to that simulated with observations for all subregions examined.

KW - climate change

KW - downscaling

KW - hydrological modeling

KW - mountainous terrain

KW - water resources

KW - western United States

UR - https://www.scopus.com/pages/publications/85174438562

U2 - 10.1029/2023GL105326

DO - 10.1029/2023GL105326

M3 - Article

AN - SCOPUS:85174438562

SN - 0094-8276

VL - 50

JO - Geophysical Research Letters

JF - Geophysical Research Letters

IS - 20

M1 - e2023GL105326

ER -

Mass-Conserving Downscaling of Climate Model Precipitation Over Mountainous Terrain for Water Resource Applications

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Keywords

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