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Integrating water availability for electrolysis into energy system modeling

Julian Walter, Lina Fischer, Sandra Venghaus, Albert Moser

2025Advances in Applied Energy9 citationsDOIOpen Access PDF

Abstract

In recent years, temperature records have been broken all over the world and the global temperature keeps rising. As a result, fresh water availability will diminish ever more and more due to droughts and extreme weather events. Water is a key part of many central aspects of life but will also become important in the future for electrolysis to synthesize hydrogen, a promising energy carrier in energy systems for the transition from fossil to renewable energy. Current energy system optimization models neglect water as an input for electrolysis when focusing on electricity. In this study, we present a method for implementing water as an input in energy system optimization models, with constraints for freshwater availability and seawater processing. We apply our method to one scenario and investigate the impact on the European energy system with highly-detailed spatial and temporal resolutions. The results indicate a relocation of electrolysis capacities of 10% and an increase of methane imports and methanation capacities. The effects suggest that water should be considered in energy system optimization in the future. • Water availability, water processing, and water input in electrolysis as constraints for energy system optimization. • Water availability influences the location and size of electrolysis and methanation systems. • Relocation of 10% of electrolysis capacities when considering water availability. • Electrolysis capacities tend to be relocated to neighboring regions or coastal regions when facing limits. • Water availability leads to 40% higher methane imports from outside of Europe.

Topics & Concepts

ElectrolysisEnvironmental scienceEnergy (signal processing)Computer scienceElectrolysis of waterProcess engineeringEngineeringChemistryPhysicsElectrolyteQuantum mechanicsElectrodePhysical chemistryIntegrated Energy Systems OptimizationHybrid Renewable Energy SystemsWater-Energy-Food Nexus Studies