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Pulsed Dynamic Water Electrolysis: Mass Transfer Enhancement, Microenvironment Regulation, and Hydrogen Production Optimization

Xuewei Zhang, Weinan Zhou, Xian-Yu Meng, Yuming Huang, Yi Yu, Haiqian Zhao, Lijie Wang, Fei Sun, Jihui Gao, Guangbo Zhao

2026Nano-Micro Letters8 citationsDOIOpen Access PDF

Abstract

Pulsed dynamic electrolysis (PDE), driven by renewable energy, has emerged as an innovative electrocatalytic conversion method, demonstrating significant potential in addressing global energy challenges and promoting sustainable development. Despite significant progress in various electrochemical systems, the regulatory mechanisms of PDE in energy and mass transfer and the lifespan extension of electrolysis systems, particularly in water electrolysis (WE) for hydrogen production, remain insufficiently explored. Therefore, there is an urgent need for a deeper understanding of the unique contributions of PDE in mass transfer enhancement, microenvironment regulation, and hydrogen production optimization, aiming to achieve low-energy consumption, high catalytic activity, and long-term stability in the generation of target products. Here, this review critically examines the microenvironmental effects of PDE on energy and mass transfer, the electrode degradation mechanisms in the lifespan extension of electrolysis systems, and the key factors in enhancing WE for hydrogen production, providing a comprehensive summary of current research progress. The review focuses on the complex regulatory mechanisms of frequency, duty cycle, amplitude, and other factors in hydrogen evolution reaction (HER) performance within PDE strategies, revealing the interrelationships among them. Finally, the potential future directions and challenges for transitioning from laboratory studies to industrial applications are proposed.

Topics & Concepts

Hydrogen productionElectrolysisBiochemical engineeringElectrolysis of waterRenewable energyProduction (economics)Water splittingHydrogenMass transferProcess engineeringEnvironmental scienceHydrogen fuelNanotechnologySustainable energyChemistryMaterials sciencePolymer electrolyte membrane electrolysisElectrochemistryHydrogen economyEnergy transformationMicrobial electrolysis cellHigh massCatalysisCurrent (fluid)Oxygen evolutionComputer scienceEnergy carrierElectrocatalysts for Energy ConversionHybrid Renewable Energy SystemsSubcritical and Supercritical Water Processes
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