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Climate and land-use change impact on faecal indicator bacteria in a temperate maritime catchment (the River Conwy, Wales). / Bussi, Gianbussi; Whitehead, Paul; Thomas, Amy et al.
Yn: Journal of Hydrology, Cyfrol 553, 10.2017, t. 248-261.

Allbwn ymchwil: Cyfraniad at gyfnodolynErthygladolygiad gan gymheiriaid

HarvardHarvard

Bussi, G, Whitehead, P, Thomas, A, Masante, D, Jones, L, Cosby, J, Emmett, B, Malham, S, Prudhomme, C & Prosser, H 2017, 'Climate and land-use change impact on faecal indicator bacteria in a temperate maritime catchment (the River Conwy, Wales)', Journal of Hydrology, cyfrol. 553, tt. 248-261. https://doi.org/10.1016/j.jhydrol.2017.08.011

APA

Bussi, G., Whitehead, P., Thomas, A., Masante, D., Jones, L., Cosby, J., Emmett, B., Malham, S., Prudhomme, C., & Prosser, H. (2017). Climate and land-use change impact on faecal indicator bacteria in a temperate maritime catchment (the River Conwy, Wales). Journal of Hydrology, 553, 248-261. https://doi.org/10.1016/j.jhydrol.2017.08.011

CBE

Bussi G, Whitehead P, Thomas A, Masante D, Jones L, Cosby J, Emmett B, Malham S, Prudhomme C, Prosser H. 2017. Climate and land-use change impact on faecal indicator bacteria in a temperate maritime catchment (the River Conwy, Wales). Journal of Hydrology. 553:248-261. https://doi.org/10.1016/j.jhydrol.2017.08.011

MLA

VancouverVancouver

Bussi G, Whitehead P, Thomas A, Masante D, Jones L, Cosby J et al. Climate and land-use change impact on faecal indicator bacteria in a temperate maritime catchment (the River Conwy, Wales). Journal of Hydrology. 2017 Hyd;553:248-261. Epub 2017 Awst 10. doi: 10.1016/j.jhydrol.2017.08.011

Author

Bussi, Gianbussi ; Whitehead, Paul ; Thomas, Amy et al. / Climate and land-use change impact on faecal indicator bacteria in a temperate maritime catchment (the River Conwy, Wales). Yn: Journal of Hydrology. 2017 ; Cyfrol 553. tt. 248-261.

RIS

TY - JOUR

T1 - Climate and land-use change impact on faecal indicator bacteria in a temperate maritime catchment (the River Conwy, Wales)

AU - Bussi, Gianbussi

AU - Whitehead, Paul

AU - Thomas, Amy

AU - Masante, Dario

AU - Jones, Laurence

AU - Cosby, Jack

AU - Emmett, Bridget

AU - Malham, Shelagh

AU - Prudhomme, Christel

AU - Prosser, Harvard

PY - 2017/10

Y1 - 2017/10

N2 - Water-borne pathogen contamination from untreated sewage effluent and runoff from farms is a serious threat to the use of river water for drinking and commercial purposes, such as downstream estuarine shellfish industries. In this study, the impact of climate change and land-use change on the presence of faecal indicator bacteria in freshwater was evaluated, through the use of a recentlydeveloped catchment-scale pathogen model. The River Conwy in Wales has been used as a case-study, because of the large presence of livestock in the catchment and the importance of the shellfish harvesting activities in its estuary. The INCA-Pathogens catchment model has been calibrated through the use of a Monte-Carlo-based technique, based on faecal indicator bacteria measurements, and then driven by an ensemble of climate projections obtained from the HadRM3-PPE model (Future Flow Climate) plus four land-use scenarios (current land use, managed ecosystem, abandonment and agricultural intensification). The results show that climate change is not expected to have a very large impact on average river flow, although it might alter its seasonality. The abundance of faecal indicator bacteria is expected to decrease in response to climate change, especially during the summer months, due to reduced precipitation, causing reduced runoff, and increased temperature, whichenhances the bacterial die-off processes. Land-use change can also have a potentially large impact on pathogens. The “managed ecosystems” scenario proposed in this study can cause a reduction of 15% in average water faecal indicator bacteria and up to 30% in the 90th percentile of water faecalindicator bacteria, mainly due to the conversion of pasture land into grassland and the expansion of forest land. This study provides an example of how to assess the impacts of human interventions on the landscape, and what may be the extent of their effects, for other catchments where the human use of the natural resources in the uplands can jeopardise the use of natural resources downstream.

AB - Water-borne pathogen contamination from untreated sewage effluent and runoff from farms is a serious threat to the use of river water for drinking and commercial purposes, such as downstream estuarine shellfish industries. In this study, the impact of climate change and land-use change on the presence of faecal indicator bacteria in freshwater was evaluated, through the use of a recentlydeveloped catchment-scale pathogen model. The River Conwy in Wales has been used as a case-study, because of the large presence of livestock in the catchment and the importance of the shellfish harvesting activities in its estuary. The INCA-Pathogens catchment model has been calibrated through the use of a Monte-Carlo-based technique, based on faecal indicator bacteria measurements, and then driven by an ensemble of climate projections obtained from the HadRM3-PPE model (Future Flow Climate) plus four land-use scenarios (current land use, managed ecosystem, abandonment and agricultural intensification). The results show that climate change is not expected to have a very large impact on average river flow, although it might alter its seasonality. The abundance of faecal indicator bacteria is expected to decrease in response to climate change, especially during the summer months, due to reduced precipitation, causing reduced runoff, and increased temperature, whichenhances the bacterial die-off processes. Land-use change can also have a potentially large impact on pathogens. The “managed ecosystems” scenario proposed in this study can cause a reduction of 15% in average water faecal indicator bacteria and up to 30% in the 90th percentile of water faecalindicator bacteria, mainly due to the conversion of pasture land into grassland and the expansion of forest land. This study provides an example of how to assess the impacts of human interventions on the landscape, and what may be the extent of their effects, for other catchments where the human use of the natural resources in the uplands can jeopardise the use of natural resources downstream.

KW - Pathogens; Water quality modelling; River Conwy; Climate change; Land-use change

U2 - 10.1016/j.jhydrol.2017.08.011

DO - 10.1016/j.jhydrol.2017.08.011

M3 - Article

VL - 553

SP - 248

EP - 261

JO - Journal of Hydrology

JF - Journal of Hydrology

SN - 0022-1694

ER -