Valued peaks: Sustainable water allocation for small hydropower plants in an era of explicit ecological needs

Faisal Bin Ashraf; Hannu Huuki; Ali Torabi Haghighi; Artti Juutinen; Atso Romakkaniemi; Hannu Marttila

doi:10.1016/j.renene.2025.122756

Valued peaks: Sustainable water allocation for small hydropower plants in an era of explicit ecological needs

Faisal Bin Ashraf
, Hannu Huuki
, Ali Torabi Haghighi
, Artti Juutinen
, Atso Romakkaniemi
, Hannu Marttila

Water Resources Science & Engineering

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

9 Scopus citations

Abstract

Optimizing hydropower operations to balance economic profitability and support functioning ecosystem services is integral to river management policy. In this article, we propose a dynamic, constrained optimization framework for small hydropower plants (SHPs) to evaluate trade-offs between economic profitability and socio-ecological requirements. Specifically, we examine the balance between short-term losses in hydropower generation and the potential for compensatory benefits in the form of revenue from recreational ecosystem services, irrespective of the direct beneficiary. Our framework integrates a fish habitat model, a hydropower optimization model, and a recreational ecosystem service estimate to evaluate different environmental flow scenarios. The optimization process gives three outflow release scenarios, informed by previous streamflow realisations (dam inflow), and designed environmental flow constraints. The framework is applied and tested for the river Kuusinkijoki in North-eastern Finland, which is a habitat for migratory brown trout and grayling populations. We show that the revenue loss due to the environmental flow constraints arises through a reduction in revenue per generated energy unit and through a reduction in turbine efficiency. Additionally, the simulation results reveal that all the designed environmental flow constraints cannot be met simultaneously. Under the environmental flow scenario with both minimum flow and flow ramping rate constraints, the annual hydropower revenue decreases by 16.5 %. An annual increase of 8 % in recreational fishing visits offsets the revenue loss. The developed framework provides knowledge of the costs and benefits of hydropower environmental flow constraints and guides the prioritizing process of environmental measures.

Original language	English
Article number	122756
Journal	Renewable Energy
Volume	244
DOIs	https://doi.org/10.1016/j.renene.2025.122756
State	Published - May 2025

Funding

Today, at least 82 891 SHPs (11 times the number of LHPs) are either in operation or under construction in 150 countries (T. B. [15]). This number could triple, with an additional 181 976 plants that could be installed if all potential capacity were to be developed (T. B. [15]). This projected rise in SHPs can have detrimental impacts on river habitat quality and affect the persistence of migratory fish and cultural ES they support [5]. Migratory fish have key roles in food webs and ecosystem functioning [24,25], hence their wellbeing can be a good gauge of how well the ecosystem is functioning. Fish habitat quality depends on hydro-morphological and ecological dynamics [26], which are fundamentally tied to water availability's spatial and temporal variability, i.e., to the flow regime [27]. The impact of SHPs on natural river flow regimes is influenced by various operational factors, such as whether the SHP is a peaking or run-of-river plant, its size, and the presence of a reservoir. While not solely dictated by market price variability, it can still be a contributing factor. As a result of these practices, hydropeaking occurs, which refers to releasing sudden flows during peak energy demand periods. Global power markets have undergone deregulation and price liberalization [28,29], with the aim of allowing them to be more competitive and efficient [30,31]. As the operational regimes of SHP connected to a deregulated market mimics the price variation in it, sub-daily flow regimes variation of such river could also exacerbate.The study was funded by the EcoRiver Assessing and valuing ecosystem services for managing hydropower constructed rivers systems -project, the Academy of Finland (grant number 323810). The BioWater project, Nordic Centre of Excellence, funded by NordForsk (Project Number 82263), Blue Innovation project funded by Swedish Research Council (Project Number 100465), and HYDRO RDI project funded by the Academy of Finland (grant number 337523) supported the writing. We thank Kimmo Aronsuu for providing local knowledge from the river Kuusinkijoki, and Olli van der Meer and Markku Lahti for sharing river bathymetry information. Faisal Bin Ashraf is an employee of UT-Battelle, LLC, under contract DE-AC05-00OR22725 with the US Department of Energy (DOE). Accordingly, the US government retains and the publisher, by accepting the article for publication, acknowledges that the US government retains a nonexclusive, paid-up, irrevocable, worldwide license to publish or reproduce the published form of this manuscript or allow others to do so, for US Government purposes. DOE will provide public access to these results of federally sponsored research in accordance with the DOE Public Access Plan (https://www.energy.gov/doe-public-access-plan). The study was funded by the EcoRiver Assessing and valuing ecosystem services for managing hydropower constructed rivers systems -project, the Academy of Finland (grant number 323810). The BioWater project, Nordic Centre of Excellence, funded by NordForsk (Project Number 82263), Blue Innovation project funded by Swedish Research Council (Project Number 100465), and HYDRO RDI project funded by the Academy of Finland (grant number 337523) supported the writing. We thank Kimmo Aronsuu for providing local knowledge from the river Kuusinkijoki, and Olli van der Meer and Markku Lahti for sharing river bathymetry information. Faisal Bin Ashraf is an employee of UT-Battelle, LLC, under contract DE-AC05-00OR22725 with the US Department of Energy (DOE). Accordingly, the US government retains and the publisher, by accepting the article for publication, acknowledges that the US government retains a nonexclusive, paid-up, irrevocable, worldwide license to publish or reproduce the published form of this manuscript or allow others to do so, for US Government purposes. DOE will provide public access to these results of federally sponsored research in accordance with the DOE Public Access Plan ( https://www.energy.gov/doe-public-access-plan )

Keywords

Ecological flow constraints
Hydropower optimization
Small hydropower
Sustainable energy

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10.1016/j.renene.2025.122756

Cite this

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title = "Valued peaks: Sustainable water allocation for small hydropower plants in an era of explicit ecological needs",

abstract = "Optimizing hydropower operations to balance economic profitability and support functioning ecosystem services is integral to river management policy. In this article, we propose a dynamic, constrained optimization framework for small hydropower plants (SHPs) to evaluate trade-offs between economic profitability and socio-ecological requirements. Specifically, we examine the balance between short-term losses in hydropower generation and the potential for compensatory benefits in the form of revenue from recreational ecosystem services, irrespective of the direct beneficiary. Our framework integrates a fish habitat model, a hydropower optimization model, and a recreational ecosystem service estimate to evaluate different environmental flow scenarios. The optimization process gives three outflow release scenarios, informed by previous streamflow realisations (dam inflow), and designed environmental flow constraints. The framework is applied and tested for the river Kuusinkijoki in North-eastern Finland, which is a habitat for migratory brown trout and grayling populations. We show that the revenue loss due to the environmental flow constraints arises through a reduction in revenue per generated energy unit and through a reduction in turbine efficiency. Additionally, the simulation results reveal that all the designed environmental flow constraints cannot be met simultaneously. Under the environmental flow scenario with both minimum flow and flow ramping rate constraints, the annual hydropower revenue decreases by 16.5 \%. An annual increase of 8 \% in recreational fishing visits offsets the revenue loss. The developed framework provides knowledge of the costs and benefits of hydropower environmental flow constraints and guides the prioritizing process of environmental measures.",

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AU - Ashraf, Faisal Bin

AU - Huuki, Hannu

AU - Torabi Haghighi, Ali

AU - Juutinen, Artti

AU - Romakkaniemi, Atso

AU - Marttila, Hannu

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N2 - Optimizing hydropower operations to balance economic profitability and support functioning ecosystem services is integral to river management policy. In this article, we propose a dynamic, constrained optimization framework for small hydropower plants (SHPs) to evaluate trade-offs between economic profitability and socio-ecological requirements. Specifically, we examine the balance between short-term losses in hydropower generation and the potential for compensatory benefits in the form of revenue from recreational ecosystem services, irrespective of the direct beneficiary. Our framework integrates a fish habitat model, a hydropower optimization model, and a recreational ecosystem service estimate to evaluate different environmental flow scenarios. The optimization process gives three outflow release scenarios, informed by previous streamflow realisations (dam inflow), and designed environmental flow constraints. The framework is applied and tested for the river Kuusinkijoki in North-eastern Finland, which is a habitat for migratory brown trout and grayling populations. We show that the revenue loss due to the environmental flow constraints arises through a reduction in revenue per generated energy unit and through a reduction in turbine efficiency. Additionally, the simulation results reveal that all the designed environmental flow constraints cannot be met simultaneously. Under the environmental flow scenario with both minimum flow and flow ramping rate constraints, the annual hydropower revenue decreases by 16.5 %. An annual increase of 8 % in recreational fishing visits offsets the revenue loss. The developed framework provides knowledge of the costs and benefits of hydropower environmental flow constraints and guides the prioritizing process of environmental measures.

AB - Optimizing hydropower operations to balance economic profitability and support functioning ecosystem services is integral to river management policy. In this article, we propose a dynamic, constrained optimization framework for small hydropower plants (SHPs) to evaluate trade-offs between economic profitability and socio-ecological requirements. Specifically, we examine the balance between short-term losses in hydropower generation and the potential for compensatory benefits in the form of revenue from recreational ecosystem services, irrespective of the direct beneficiary. Our framework integrates a fish habitat model, a hydropower optimization model, and a recreational ecosystem service estimate to evaluate different environmental flow scenarios. The optimization process gives three outflow release scenarios, informed by previous streamflow realisations (dam inflow), and designed environmental flow constraints. The framework is applied and tested for the river Kuusinkijoki in North-eastern Finland, which is a habitat for migratory brown trout and grayling populations. We show that the revenue loss due to the environmental flow constraints arises through a reduction in revenue per generated energy unit and through a reduction in turbine efficiency. Additionally, the simulation results reveal that all the designed environmental flow constraints cannot be met simultaneously. Under the environmental flow scenario with both minimum flow and flow ramping rate constraints, the annual hydropower revenue decreases by 16.5 %. An annual increase of 8 % in recreational fishing visits offsets the revenue loss. The developed framework provides knowledge of the costs and benefits of hydropower environmental flow constraints and guides the prioritizing process of environmental measures.

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Valued peaks: Sustainable water allocation for small hydropower plants in an era of explicit ecological needs

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