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Cape Fear River Basin Water Quantity and Quality Model

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Owners:		This resource does not have an owner who is an active HydroShare user. Contact CUAHSI (help@cuahsi.org) for information on this resource.
Type:	Resource
Storage:	The size of this resource is 1.2 GB
Created:	Jun 23, 2024 at 11:19 p.m. (UTC)
Last updated:	Nov 26, 2024 at 6:28 p.m. (UTC)
Published date:	Nov 26, 2024 at 6:28 p.m. (UTC)
DOI:	10.4211/hs.e309c3c2c5db4bacb49b3d9a0761ce2b
Citation:	See how to cite this resource

Sharing Status:	Published
Views:	1997
Downloads:	62
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Abstract

This resource contains the Cape Fear River Basin Water Quantity and Quality Soil and Water Assessment Tool Model (CFRB WQQ SWAT Model) which was the basis of the publication "Landscape pollution source dynamics highlight priority locations for basin-scale interventions to protect water quality under hydroclimatic variability".

The CFRB WQQ SWAT Model was developed by The Nature Conservancy and Arizona State University to examine risks to water quality from point and non-point sources under current land use and weather conditions from 1982-2019, and to facilitate the evaluation of scenarios, including watershed-scale restoration of forests and wetlands. This model was modified from a Cape Fear River Basin Water Quantity Model developed by the U.S. Geological Survey South Atlantic Water Science Center for a Coastal Carolinas Focus Area Study of water availability and water use.

Materials contained in this resource include:
-CFRB WQQ SWAT Model
-Model data delineating the watershed boundary, model subbasins, reach network, and subbasin outlets, as well as input data including land use, soil, and slope, and reservoir and pond parameters
-Additional simulation input files that permit changing the simulation period

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Related Resources

This resource is referenced by	Schaffer-Smith, D., J. E. DeMeester, D. Tong, S. W. Myint, D. A. Libera, R. L. Muenich (2023). Supporting data: "Landscape pollution source dynamics highlight priority locations for basin-scale interventions to protect water quality under hydroclimatic variability", HydroShare, https://doi.org/10.4211/hs.a5f2049820db480fa3e03c0ea7216b56
This resource is described by	Schaffer-Smith, D., DeMeester, J. E.,Tong, D., Myint, S. W., Libera, D. A.,& Muenich, R. L. (2023). Landscape pollution source dynamics highlight priority locations for basin-scale interventions to protect water quality under hydroclimatic variability. Earth'sFuture, 11, e2022EF003137. https://doi.org/10.1029/2022EF003137
This resource is described by	Gurley, L. N., García, A. M. & Pfeifle, C. M. Soil and Water Assessment Tool (SWAT) models for the Cape Fear River Basin used to simulate future streamflow and irrigation demand based on climate and urban growth projections. (2023) doi:10.5066/P98PVDBW.

Credits

Funding Agencies

This resource was created using funding from the following sources:

Agency Name	Award Title	Award Number
The Nature Conservancy	NatureNet Science Fellowship	None
Arizona State University	NatureNet Science Fellowship	None
North Carolina Attorney General's Office	Environmental Enhancement Grant	None

How to Cite

Schaffer-Smith, D., R. Muenich, D. A. Libera, D. Tong, S. W. Myint, J. E. DeMeester (2024). Cape Fear River Basin Water Quantity and Quality Model, HydroShare, https://doi.org/10.4211/hs.e309c3c2c5db4bacb49b3d9a0761ce2b

This resource is shared under the Creative Commons Attribution CC BY.

http://creativecommons.org/licenses/by/4.0/

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