TY - JOUR AU - Pablo A García-Salaberri AU - Lonneke van Eijk AU - William Bangay AU - Kara J Ferner AU - Mee H Ha AU - Michael Moore AU - Ivan Perea AU - Ahmet Kusoglu AU - Marc Secanell AU - Prodip K Das AU - Nausir Mahmoud Firas AU - Svitlana Pylypenko AU - Melissa Novy AU - Michael A Yandrasits AU - Suvash C Saha AU - Ali Bayat AU - Shawn Litster AU - Iryna V Zenyuk AB -
Proton exchange membrane water electrolyzers (PEMWEs) are expected to play a crucial role in the global green energy transition during the 21st century. They provide a versatile and sustainable solution for generating hydrogen with very high purity in combination with renewable energies, such as solar and wind. Despite their promise, PEMWEs face several critical problems, including high costs, performance limitations, and durability challenges, particularly at low iridium (Ir) loading on the anode. Advancing next-generation PEMWEs requires extensive work on materials engineering of all cell components, including the catalyst layer (CL), membrane, porous transport layer (PTL), bipolar plate (BPP), and gasket. This task must be performed with the complementary contribution of different modeling and characterization techniques. This review presents a critical perspective from academia, research centers, and industry, mapping main developments, remaining gaps, and strategic pathways to advance PEMWE technology. A focus is devoted to key aspects, such as operation at low Ir loading, membrane durability, multiscale transport layers, porous and non-porous flow fields, multiphysics modeling, and multipurpose characterization techniques, which are thoroughly discussed. By unifying these topics, this review provides readers with the essential knowledge to grasp current developments and tackle tomorrow’s challenges in PEMWE engineering.
BT - ACS Applied Energy Materials DA - 22/09/2025 DO - 10.1021/acsaem.5c01989 IS - 18 N2 -Proton exchange membrane water electrolyzers (PEMWEs) are expected to play a crucial role in the global green energy transition during the 21st century. They provide a versatile and sustainable solution for generating hydrogen with very high purity in combination with renewable energies, such as solar and wind. Despite their promise, PEMWEs face several critical problems, including high costs, performance limitations, and durability challenges, particularly at low iridium (Ir) loading on the anode. Advancing next-generation PEMWEs requires extensive work on materials engineering of all cell components, including the catalyst layer (CL), membrane, porous transport layer (PTL), bipolar plate (BPP), and gasket. This task must be performed with the complementary contribution of different modeling and characterization techniques. This review presents a critical perspective from academia, research centers, and industry, mapping main developments, remaining gaps, and strategic pathways to advance PEMWE technology. A focus is devoted to key aspects, such as operation at low Ir loading, membrane durability, multiscale transport layers, porous and non-porous flow fields, multiphysics modeling, and multipurpose characterization techniques, which are thoroughly discussed. By unifying these topics, this review provides readers with the essential knowledge to grasp current developments and tackle tomorrow’s challenges in PEMWE engineering.
PB - American Chemical Society (ACS) PY - 2025 SP - 13050 EP - 13121 T2 - ACS Applied Energy Materials TI - Materials Engineering for High Performance and Durability Proton Exchange Membrane Water Electrolyzers UR - https://doi.org/10.1021/acsaem.5c01989 VL - 8 SN - 2574-0962, 2574-0962 ER -