Hydrologic sensitivity of a critical Turkish watershed to inform water resource management in an altered climate
Hydrologic sensitivity of a critical Turkish watershed to inform water resource management in an altered climate
This study introduces a novel sensitivity analysis approach to assess the resilience and susceptibility of hydrologic systems to the stresses of climate change, moving away from conventional top-down methodologies. By exploring the hydrological sensitivity of the upper Kızılırmak River basin using the Variable Infiltration Capacity (VIC) hydrologic model, we employed a sensitivity-based approach as an alternative to the traditional Global Climate Model (GCM)-based methods, providing more insightful information for water managers. Considering the consistent projections of increasing temperature over this region in GCMs, the hydrologic system was perturbed to examine gradients of a more challenging climate characterized by warming and drying conditions. The sensitivity of streamflow, snow water equivalent, and evapotranspiration to temperature (T) and precipitation (P) variations under each perturbation or “reference” climate was quantified. Results indicate that streamflow responds to T negatively under all warming scenarios. As the reference climates become drier, streamflow sensitivity to P increases, indicating that meteorological drought impacts on water availability could be exacerbated. These results suggest that there will be heightened difficulty in managing water resources in the region if it undergoes both warming and drying due to the following setbacks: (1) water availability will shift away from the summer season of peak water demand due to the warming effects on the snowpack, (2) annual water availability will likely decrease due to a combination of warming and lower precipitation, and (3) streamflow sensitivity to hydroclimatic variability will increase, meaning that there will be more extreme impacts to water availability. Water managers will need to plan for a larger set of extreme conditions.
climate change, hydrologic sensitivity, variable infiltration capacity model
Cevahir, Furkan Yunus Emre
d4caa72f-d968-402b-a766-041c043e7854
Adam, Jennifer C.
56d46f5a-b6e9-4edc-bf24-8bb282b1120d
Liu, Mingliang
c9829a5e-5a66-45cb-a866-7ee9c1515455
Sheffield, Justin
dd66575b-a4dc-4190-ad95-df2d6aaaaa6b
30 April 2024
Cevahir, Furkan Yunus Emre
d4caa72f-d968-402b-a766-041c043e7854
Adam, Jennifer C.
56d46f5a-b6e9-4edc-bf24-8bb282b1120d
Liu, Mingliang
c9829a5e-5a66-45cb-a866-7ee9c1515455
Sheffield, Justin
dd66575b-a4dc-4190-ad95-df2d6aaaaa6b
Cevahir, Furkan Yunus Emre, Adam, Jennifer C., Liu, Mingliang and Sheffield, Justin
(2024)
Hydrologic sensitivity of a critical Turkish watershed to inform water resource management in an altered climate.
Hydrology, 11 (5), [64].
(doi:10.3390/hydrology11050064).
Abstract
This study introduces a novel sensitivity analysis approach to assess the resilience and susceptibility of hydrologic systems to the stresses of climate change, moving away from conventional top-down methodologies. By exploring the hydrological sensitivity of the upper Kızılırmak River basin using the Variable Infiltration Capacity (VIC) hydrologic model, we employed a sensitivity-based approach as an alternative to the traditional Global Climate Model (GCM)-based methods, providing more insightful information for water managers. Considering the consistent projections of increasing temperature over this region in GCMs, the hydrologic system was perturbed to examine gradients of a more challenging climate characterized by warming and drying conditions. The sensitivity of streamflow, snow water equivalent, and evapotranspiration to temperature (T) and precipitation (P) variations under each perturbation or “reference” climate was quantified. Results indicate that streamflow responds to T negatively under all warming scenarios. As the reference climates become drier, streamflow sensitivity to P increases, indicating that meteorological drought impacts on water availability could be exacerbated. These results suggest that there will be heightened difficulty in managing water resources in the region if it undergoes both warming and drying due to the following setbacks: (1) water availability will shift away from the summer season of peak water demand due to the warming effects on the snowpack, (2) annual water availability will likely decrease due to a combination of warming and lower precipitation, and (3) streamflow sensitivity to hydroclimatic variability will increase, meaning that there will be more extreme impacts to water availability. Water managers will need to plan for a larger set of extreme conditions.
Text
hydrology-11-00064-v2 (1)
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More information
Accepted/In Press date: 25 April 2024
Published date: 30 April 2024
Keywords:
climate change, hydrologic sensitivity, variable infiltration capacity model
Identifiers
Local EPrints ID: 493573
URI: http://eprints.soton.ac.uk/id/eprint/493573
PURE UUID: 46d279ae-4959-4613-88e8-5af05dd834ed
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Date deposited: 06 Sep 2024 16:46
Last modified: 07 Sep 2024 01:48
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Contributors
Author:
Furkan Yunus Emre Cevahir
Author:
Jennifer C. Adam
Author:
Mingliang Liu
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