Soil Water Assessment Tool (SWAT) simulated hydrological impacts of land use change from temperate grassland to energy crops: a case study in western UK

Amanda J Holder; Rebecca Rowe; Niall P. McNamara; Iain S. Donnison; Jon McCalmont

doi:10.1111/gcbb.12628

Soil Water Assessment Tool (SWAT) simulated hydrological impacts of land use change from temperate grassland to energy crops: a case study in western UK

Amanda J Holder^* (Corresponding Author), Rebecca Rowe, Niall P. McNamara, Iain S. Donnison, Jon McCalmont

^*Corresponding author for this work

Aberdeen Centre For Environmental Sustainability

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

4 Citations (Scopus)

Abstract

When considering the large-scale deployment of bioenergy crops, it is important to understand the implication for ecosystem hydrological processes and the influences of crop type and location. Based on the potential for future land use change (LUC), the 10,280 km2 West Wales Water Framework Directive River Basin District (UK) was selected as a typical grassland dominated district, and the Soil & Water Assessment Tool (SWAT) hydrology model with a geographic information systems interface was used to investigate implications for different bioenergy deployment scenarios. The study area was delineated into 855 sub-basins and 7,108 hydrological response units based on rivers, soil type, land use, and slope. Changes in hydrological components for two bioenergy crops (Miscanthus and short rotation coppice, SRC) planted on 50% (2,192 km2) or 25% (1,096 km2) of existing improved pasture are quantified. Across the study area as a whole, only surface run-off with SRC planted at the 50% level was significantly impacted, where it was reduced by up to 23% (during April). However, results varied spatially and a comparison of annual means for each sub-basin and scenario revealed surface run-off was significantly decreased and baseflow significantly increased (by a maximum of 40%) with both Miscanthus and SRC. Evapotranspiration was significantly increased with SRC (at both planting levels) and water yield was significantly reduced with SRC (at the 50% level) by up to 5%. Effects on streamflow were limited, varying between −5% and +5% change (compared to baseline) in the majority of sub-basins. The results suggest that for mesic temperate grasslands, adverse effects from the drying of soil and alterations to streamflow may not arise, and with surface run-off reduced and baseflow increased, there could, depending on crop location, be potential benefits for flood and erosion mitigation.

Original language	English
Pages (from-to)	1298-1317
Number of pages	20
Journal	Global Change Biology. Bioenergy
Volume	11
Issue number	11
Early online date	26 Jul 2019
DOIs	https://doi.org/10.1111/gcbb.12628
Publication status	Published - Nov 2019

Keywords

bioenergy
evapotranspiration
flooding
hidrology
MIscanthus
short rotation coppice
Streamflow

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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© 2019 The Authors. GCB Bioenergy Published by John Wiley & Sons Ltd This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited. https://creativecommons.org/licenses/by/4.0/
Final published version, 1.56 MBLicence: CC BY

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Soil Water Assessment Tool (SWAT) simulated hydrological impacts of land use change from temperate grassland to energy crops: a case study in western UK. / Holder, Amanda J (Corresponding Author); Rowe, Rebecca; McNamara, Niall P. et al.

In: Global Change Biology. Bioenergy, Vol. 11, No. 11, 11.2019, p. 1298-1317.

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

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title = "Soil Water Assessment Tool (SWAT) simulated hydrological impacts of land use change from temperate grassland to energy crops: a case study in western UK",

abstract = "When considering the large-scale deployment of bioenergy crops, it is important to understand the implication for ecosystem hydrological processes and the influences of crop type and location. Based on the potential for future land use change (LUC), the 10,280 km2 West Wales Water Framework Directive River Basin District (UK) was selected as a typical grassland dominated district, and the Soil & Water Assessment Tool (SWAT) hydrology model with a geographic information systems interface was used to investigate implications for different bioenergy deployment scenarios. The study area was delineated into 855 sub-basins and 7,108 hydrological response units based on rivers, soil type, land use, and slope. Changes in hydrological components for two bioenergy crops (Miscanthus and short rotation coppice, SRC) planted on 50% (2,192 km2) or 25% (1,096 km2) of existing improved pasture are quantified. Across the study area as a whole, only surface run-off with SRC planted at the 50% level was significantly impacted, where it was reduced by up to 23% (during April). However, results varied spatially and a comparison of annual means for each sub-basin and scenario revealed surface run-off was significantly decreased and baseflow significantly increased (by a maximum of 40%) with both Miscanthus and SRC. Evapotranspiration was significantly increased with SRC (at both planting levels) and water yield was significantly reduced with SRC (at the 50% level) by up to 5%. Effects on streamflow were limited, varying between −5% and +5% change (compared to baseline) in the majority of sub-basins. The results suggest that for mesic temperate grasslands, adverse effects from the drying of soil and alterations to streamflow may not arise, and with surface run-off reduced and baseflow increased, there could, depending on crop location, be potential benefits for flood and erosion mitigation.",

keywords = "bioenergy, evapotranspiration, flooding, hidrology, MIscanthus, short rotation coppice, Streamflow",

author = "Holder, {Amanda J} and Rebecca Rowe and McNamara, {Niall P.} and Donnison, {Iain S.} and Jon McCalmont",

note = "ACKNOWLEDGEMENTS We are grateful for funding supplied by the Institute of Biology, Environment and Rural Sciences (IBERS), Aberystwyth University (IBERS receives strategic funding from BBSRC). Both IBERS and CEH were supported by MAGLUE (www.maglue.ac.uk), an EPSRC-funded project (EP/M013200/1). The field site used for some of the Miscanthus crop measurements was originally developed and instrumented as part of the Carbo-biocrop (NE/H01067X/1) and Energy Technologies Institute-funded ELUM (www.elum.ac.uk) projects.",

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AU - Donnison, Iain S.

AU - McCalmont, Jon

N1 - ACKNOWLEDGEMENTS We are grateful for funding supplied by the Institute of Biology, Environment and Rural Sciences (IBERS), Aberystwyth University (IBERS receives strategic funding from BBSRC). Both IBERS and CEH were supported by MAGLUE (www.maglue.ac.uk), an EPSRC-funded project (EP/M013200/1). The field site used for some of the Miscanthus crop measurements was originally developed and instrumented as part of the Carbo-biocrop (NE/H01067X/1) and Energy Technologies Institute-funded ELUM (www.elum.ac.uk) projects.

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N2 - When considering the large-scale deployment of bioenergy crops, it is important to understand the implication for ecosystem hydrological processes and the influences of crop type and location. Based on the potential for future land use change (LUC), the 10,280 km2 West Wales Water Framework Directive River Basin District (UK) was selected as a typical grassland dominated district, and the Soil & Water Assessment Tool (SWAT) hydrology model with a geographic information systems interface was used to investigate implications for different bioenergy deployment scenarios. The study area was delineated into 855 sub-basins and 7,108 hydrological response units based on rivers, soil type, land use, and slope. Changes in hydrological components for two bioenergy crops (Miscanthus and short rotation coppice, SRC) planted on 50% (2,192 km2) or 25% (1,096 km2) of existing improved pasture are quantified. Across the study area as a whole, only surface run-off with SRC planted at the 50% level was significantly impacted, where it was reduced by up to 23% (during April). However, results varied spatially and a comparison of annual means for each sub-basin and scenario revealed surface run-off was significantly decreased and baseflow significantly increased (by a maximum of 40%) with both Miscanthus and SRC. Evapotranspiration was significantly increased with SRC (at both planting levels) and water yield was significantly reduced with SRC (at the 50% level) by up to 5%. Effects on streamflow were limited, varying between −5% and +5% change (compared to baseline) in the majority of sub-basins. The results suggest that for mesic temperate grasslands, adverse effects from the drying of soil and alterations to streamflow may not arise, and with surface run-off reduced and baseflow increased, there could, depending on crop location, be potential benefits for flood and erosion mitigation.

AB - When considering the large-scale deployment of bioenergy crops, it is important to understand the implication for ecosystem hydrological processes and the influences of crop type and location. Based on the potential for future land use change (LUC), the 10,280 km2 West Wales Water Framework Directive River Basin District (UK) was selected as a typical grassland dominated district, and the Soil & Water Assessment Tool (SWAT) hydrology model with a geographic information systems interface was used to investigate implications for different bioenergy deployment scenarios. The study area was delineated into 855 sub-basins and 7,108 hydrological response units based on rivers, soil type, land use, and slope. Changes in hydrological components for two bioenergy crops (Miscanthus and short rotation coppice, SRC) planted on 50% (2,192 km2) or 25% (1,096 km2) of existing improved pasture are quantified. Across the study area as a whole, only surface run-off with SRC planted at the 50% level was significantly impacted, where it was reduced by up to 23% (during April). However, results varied spatially and a comparison of annual means for each sub-basin and scenario revealed surface run-off was significantly decreased and baseflow significantly increased (by a maximum of 40%) with both Miscanthus and SRC. Evapotranspiration was significantly increased with SRC (at both planting levels) and water yield was significantly reduced with SRC (at the 50% level) by up to 5%. Effects on streamflow were limited, varying between −5% and +5% change (compared to baseline) in the majority of sub-basins. The results suggest that for mesic temperate grasslands, adverse effects from the drying of soil and alterations to streamflow may not arise, and with surface run-off reduced and baseflow increased, there could, depending on crop location, be potential benefits for flood and erosion mitigation.

KW - bioenergy

KW - evapotranspiration

KW - flooding

KW - hidrology

KW - MIscanthus

KW - short rotation coppice

KW - Streamflow

U2 - 10.1111/gcbb.12628

DO - 10.1111/gcbb.12628

M3 - Article

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SP - 1298

EP - 1317

JO - Global Change Biology. Bioenergy

JF - Global Change Biology. Bioenergy

SN - 1757-1693

IS - 11

ER -

Soil Water Assessment Tool (SWAT) simulated hydrological impacts of land use change from temperate grassland to energy crops: a case study in western UK

Abstract

Keywords

UN SDGs

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