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Assessing small hydropower viability in water-scarce regions: environmental flow and climate change impacts using a SWAT+ based tool
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Assessing small hydropower viability in water-scarce regions: environmental flow and climate change impacts using a SWAT+ based tool
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Journal Article
Assessing small hydropower viability in water-scarce regions: environmental flow and climate change impacts using a SWAT+ based tool
2024
Overview
Water-scarce regions, like the Mediterranean, face worsening conditions due to climate change, intensifying pressure on key economic sectors such as hydropower. Additionally, environmental conservation policies, particularly the implementation of environmental flows, present challenges for hydropower systems. Certainty regarding the impact of these factors on future hydropower production is crucial for informed decision-making in the transition to sustainable energy. This study introduces
S
+
HydPower
, a tool coupled with SWAT+ to assess climate change and watershed management effects on small hydropower plant (SHP) systems. In this study, we used this tool to investigate the consequences of implementing environmental flows and climate change on run-of-river SHPs in the Catalan River Basin District (CRBD), in Catalonia. The results show that applying environmental flows would lead to a significant 27% reduction in SHP production. However, this reduction would represent only 0.25% of the region’s current energy demand. Furthermore, the study reveals a potential 38% to 73% reduction in SHP production by the end of the twenty-first century due to the combined effects of environmental flows and climate change. This suggests a substantial decline in run-of-river SHP’s contribution to the CRBD’s electricity supply. These findings emphasize the need to explore alternative and sustainable energy sources to ensure the long-term reliability and resilience of the region’s energy supply.
Publisher
Springer Berlin Heidelberg,Springer Nature B.V,SpringerOpen
