Both reservoirs and run of river power plants affect the thermal regime of rivers but despite the higher number of the latter few studies have focused on their effect. In this study, we investigated the water thermal regime of Serio River (Northern Italy), a subalpine river regulated by a reservoir and characterized by a cascade system of run of river power plants. Water temperature has been monitored continuously for more than 4 years at the extremes of 4 stretches subjected to water diversion and thermal alterations have been quantified. Our results show that hydroelectric power plants act locally causing a considerable thermal alteration that increases with the distance from the diversion weir. Indeed, within the by-passed stretch, the rate of warming doubles the natural gradient (0.47 degrees C/km vs. 0.19 degrees C/km annually) with peaks in summer (0.73-0.90 degrees C/km on average). By contrast, the run of river power plants keep the water temperature almost constant in the diversion channels. Thus, a cascade system of run of river plants shifts the overall riverine thermal regime from a continuous to a "stepped" longitudinal profile. Results highlight that the thermal effects of run of rivers plants are not negligible and should be considered and monitored continuously. Since there are thousands of hydropower plants powered by flowing waters it is time to consider their thermal impacts in environmental flow policies and bioassessment programs.

Bonacina, L., Mezzanotte, V., Fornaroli, R. (2023). From a continuous thermal profile to a stepped one: The effect of run of river hydropower plants on the river thermal regime. RIVER RESEARCH AND APPLICATIONS, 39(6 (July 2023)), 1122-1135 [10.1002/rra.4134].

From a continuous thermal profile to a stepped one: The effect of run of river hydropower plants on the river thermal regime

Bonacina, L
Primo
;
Mezzanotte, V;Fornaroli, R
Ultimo
2023

Abstract

Both reservoirs and run of river power plants affect the thermal regime of rivers but despite the higher number of the latter few studies have focused on their effect. In this study, we investigated the water thermal regime of Serio River (Northern Italy), a subalpine river regulated by a reservoir and characterized by a cascade system of run of river power plants. Water temperature has been monitored continuously for more than 4 years at the extremes of 4 stretches subjected to water diversion and thermal alterations have been quantified. Our results show that hydroelectric power plants act locally causing a considerable thermal alteration that increases with the distance from the diversion weir. Indeed, within the by-passed stretch, the rate of warming doubles the natural gradient (0.47 degrees C/km vs. 0.19 degrees C/km annually) with peaks in summer (0.73-0.90 degrees C/km on average). By contrast, the run of river power plants keep the water temperature almost constant in the diversion channels. Thus, a cascade system of run of river plants shifts the overall riverine thermal regime from a continuous to a "stepped" longitudinal profile. Results highlight that the thermal effects of run of rivers plants are not negligible and should be considered and monitored continuously. Since there are thousands of hydropower plants powered by flowing waters it is time to consider their thermal impacts in environmental flow policies and bioassessment programs.
Articolo in rivista - Articolo scientifico
bioassessment; climate change; e-flow; flow regulation; renewable energy; thermal alterations;
English
4-apr-2023
2023
39
6 (July 2023)
1122
1135
open
Bonacina, L., Mezzanotte, V., Fornaroli, R. (2023). From a continuous thermal profile to a stepped one: The effect of run of river hydropower plants on the river thermal regime. RIVER RESEARCH AND APPLICATIONS, 39(6 (July 2023)), 1122-1135 [10.1002/rra.4134].
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/10281/424020
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