Recent Advances in Membrane Electrode Assembly for Anion Exchange Membrane Water Electrolysis: Performance and Durability Enhancement

Rongfu Hong; Jing Su; Jiayang Li; Jian Gu; Shuting Lin; Zhun Dong; Yunsong Yang; Junke Tang; Yuquan Zou; Lixin Xing; Lei Du; Hong Ren; Siyu Ye

doi:10.1007/s41918-026-00281-4

Electrochemical Energy Reviews ›› 2026, Vol. 9 ›› Issue (1) :8 DOI: 10.1007/s41918-026-00281-4

Review Article

review-article

Recent Advances in Membrane Electrode Assembly for Anion Exchange Membrane Water Electrolysis: Performance and Durability Enhancement

Author information +

¹Huangpu Hydrogen Energy Innovation Centre, School of Chemistry and Chemical Engineering, Guangzhou University, 510006, Guangzhou, Guangdong, China

², SinoHykey Technology Company Ltd., 510760, Guangzhou, Guangdong, China

^a lei.du@gzhu.edu.cn

^b hong.ren@sinohykey.com

^c siyu.ye@gzhu.edu.cn

Rongfu Hong

Rongfu Hong received his master’s degree from Guangzhou University in 2025. He is now a research assistant in Prof. Siyu Ye’s group. His research interests primarily focus on the development and application of essential materials for electrolytic hydrogen production.

Jing Su

Jing Su received her master’s degree from the Guangzhou Institute of Energy Conversion, Chinese Academy of Sciences in 2019. After graduation, she joined the research and development department of SinoHyKey (2019–2025) as an R&D engineer. Her research focuses on the development and research of the formulation of inks and the key raw materials such as membranes and ionomers.

Jiayang Li

Jiayang Li received her bachelor’s degree in chemical engineering and technology at the Hunan City University in 2022, followed by pursuing the master’s degree at the Guangzhou University (2022–2025). Her research interests focus on electrochemistry and hydrogen energy.

Jian Gu

Jian Gu obtained his Master′s degree in Chemistry from the College of Materials Science and Engineering at Huaqiao University. At Sinohykey, he focuses on the design and manufacturing of AEMWE CCMs.

Shuting Lin

Shuting Lin obtained her Bachelor's degree in Polymer Materials and Engineering from Dongguan University of Technology. At Sinohykey, she focuses on the design, manufacturing and testing of AEMWE CCMs.

Zhun Dong

Zhun Dong joined Sinohykey Co., Ltd. in September 2023 as the Project Leader for the Anion Exchange Membrane Water Electrolysis (AEMWE) project, where he specializes in MEA design and development. He earned his Ph.D. degree in Chemical Engineering and Bioengineering from Washington State University in 2023. Dr. Dong has authored 20 research articles in high-impact journals such as Applied Catalysis B: Environmental, ACS Catalysis, Small, and ChemSusChem, which have garnered over 400 citations.

Yunsong Yang

Yunsong Yang received his Ph.D. degree in polymer science and physics from Zhejiang University in 1998, followed by postdoctoral fellowships at Japan Science and Technology Agency (JST) and Simon Fraser University. He joined Ballard Power Systems (2007) and then automotive fuel cell corporation (AFCC) (2008) working on proton exchange membrane and MEA for PEM fuel cells. In 2018, he joined SinoHyKey Technology Company Ltd., as the director of the research and development department. He focuses on research and development of the MEA materials and catalyst layer designing for the PEMFC and PEMWE.

Junke Tang

Junke Tang is the head of SinoHyKey’s production operations. Prior to joining the company, Dr. Tang led the development of China’s first polymer electrolyte membrane production line, and has been awarded over fifty patents, eight of which are international. With his expertise in high precision, ultra-thin membrane technology, and its engineering processes, he has since come to establish SinoHyKey’s roll-to-roll CCM coating line and make significant advancements in the commercialization of high-performance MEAs.

Yuquan Zou

Yuquan Zou obtained his Ph.D. degree from the University of Singapore majoring in polymer chemistry. After his postdoctoral research at the University of British Columbia, Dr. Zou joined the automotive fuel cell corporation (AFCC) that was a joint venture between Daimler and Ford. His fuel cell expertise covers ionomer and membrane characterization, CCM design and manufacturing. He is currently CEO of SinoHyKey Technology Company Ltd.

Lixin Xing

Lixin Xing is currently a lecturer at Guangzhou University. She received her Ph.D. degree at the year of 2016 from Harbin Institute of Technology. She was studying at the Pennsylvania State University as a visiting student directed by Prof. Qing Wang. Her research is focused on fundamental study and high-performance functional nanocomposite for electrochemical energy conversion and storage.

Lei Du

Lei Du is an Associate Professor at the Guangzhou University. Before moving to Guangzhou, he was a postdoctoral fellow at Institut National de la Recherche Scientifique (INRS, Canada) and a lecturer at the Harbin Institute of Technology (China). He received a Ph.D. degree in 2017 from the Harbin Institute of Technology. His main research interests include electrocatalysis in energy conversion and storagenew materials, new mechanisms, and electrochemical device integration. He is the recipient of the Outstanding Youth Project of Natural Science Foundation of Guangdong Province, and is named to the Elsevier/Stanford University’s Top 2% Scientist list (2023–2025).

Hong Ren

Hong Ren is a Senior Engineer at SinoHyKey. She received her Ph.D. degree in 2023 from the Dalian Institute of Chemical Physics, Chinese Academy of Sciences. Her doctoral and current research has been centered on hydrogen energy, specializing in the development of catalyst layer/MEA and related key materials.

Siyu Ye

Siyu Ye is a fellow of the Canadian Academy of Engineering, a professor at the Guangzhou University, and a Chair and Chief Technology Officer at SinoHykey. He is recognized as a world-leading expert in electrocatalysis and catalyst layer/MEA design for fuel cells and water electrolysis, and has made significant contributions to the advancement of the modern protonic exchange membrane fuel cell and electrolysis cell.

Show less

History +

PDF

Abstract

Recently, anion exchange membrane water electrolysis (AEMWE) has garnered significant global attention due to its promising potential in energy applications. The capabilities of AEMWE are increasingly recognized for their broad prospects in sustainable energy solutions. However, AEMWE currently still faces several challenges, particularly in terms of high costs and limited durability. These challenges are primarily influenced by the performance of the membrane electrode assemblies (MEAs), which are considered the "core" components of AEMWE. As a result, substantial efforts are focused on developing innovative materials and optimizing manufacturing processes to advance AEMWE. In this review, we provide a comprehensive review of the latest developments in key materials for AEMWE, with particular emphasis on how these advanced materials can be integrated into electrodes and MEAs. Additionally, future research and development directions for materials and MEA technologies are discussed. Our aim is to bridge the gap between academic research and industrial manufacturing processes, thereby fostering the continued advancement of AEMWE. Through this discussion, we seek to facilitate the widespread application of AEMWE in the energy sector and strengthen the connection between academic research and industrial practices.

Graphical Abstract

Keywords

Hydrogen production / Anion exchange membrane water electrolysis / Key materials / Membrane electrode assembly

Cite this article

Download citation ▾

Rongfu Hong, Jing Su, Jiayang Li, Jian Gu, Shuting Lin, Zhun Dong, Yunsong Yang, Junke Tang, Yuquan Zou, Lixin Xing, Lei Du, Hong Ren, Siyu Ye. Recent Advances in Membrane Electrode Assembly for Anion Exchange Membrane Water Electrolysis: Performance and Durability Enhancement. Electrochemical Energy Reviews, 2026, 9(1): 8 DOI:10.1007/s41918-026-00281-4

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Zheng YW, Ma WC, Serban A, et al. . Anion exchange membrane water electrolysis at 10 A cm⁻² over 800 hours. Angew. Chem. Int. Ed., 2025, 64 e202413698

[2]	Mo SY, Du L, Huang ZY, et al. . Recent advances on PEM fuel cells: from key materials to membrane electrode assembly. Electrochem. Energy Rev., 2023, 6 28

[3]	Liu HY, Zhao J, Li XG. Controlled synthesis of carbon-supported Pt-based electrocatalysts for proton exchange membrane fuel cells. Electrochem. Energy Rev., 2022, 5 13

[4]	Ding MY, Jiang WJ, Yu TQ, et al. . Electronically modulated FeNi composite by CeO₂ porous nanosheets for water splitting at large current density. J. Electrochem., 2023, 29: 2208121

[5]	Zhang RL, Li YZ, Zhou X, et al. . Single-atomic platinum on fullerene C₆₀ surfaces for accelerated alkaline hydrogen evolution. Nat. Commun., 2023, 14 2460

[6]	Zhang X, Tong L, Shi XH, et al. . Tailoring atomically local electric field of NiFe layered double hydroxides with Ag dopants to boost oxygen evolution kinetics. J. Colloid Interface Sci., 2024, 668: 502-511

[7]	Wang JY, Yang JB, Feng Y, et al. . Comparative experimental study of alkaline and proton exchange membrane water electrolysis for green hydrogen production. Appl. Energy, 2025, 379 124936

[8]	Yu FY, Lang ZL, Yin LY, et al. . Pt-O bond as an active site superior to Pt⁰ in hydrogen evolution reaction. Nat. Commun., 2020, 11 490

[9]	Jiang ZT, Yi GQ, Yao X, et al. . Durable and highly-efficient anion exchange membrane water electrolysis using poly(biphenyl alkylene) membrane. Chem. Eng. J., 2023, 467 143442

[10]	Ham K, Bae S, Lee J. Classification and technical target of water electrolysis for hydrogen production. J. Energy Chem., 2024, 95: 554-576

[11]	Klingenhof M, Trzesniowski H, Koch S, et al. . High-performance anion-exchange membrane water electrolysers using NiX (X = Fe Co, Mn) catalyst-coated membranes with redox-active Ni–O ligands. Nat. Catal., 2024, 7: 1213-1222

[12]	Hyun J, Hwan Yang S, Wook Lee D, et al. . Impact of the binding ability of anion exchange ionomer on the initial performance degradation of anion exchange membrane water electrolyzers. Chem. Eng. J., 2023, 469 143919

[13]	Wang M, Ma WS, Tan CW, et al. . Designing efficient non-precious metal electrocatalysts for high-performance hydrogen production: a comprehensive evaluation strategy. Small, 2024, 20: 2306631

[14]	Zeng SP, Shi H, Dai TY, et al. . Lamella-heterostructured nanoporous bimetallic iron-cobalt alloy/oxyhydroxide and cerium oxynitride electrodes as stable catalysts for oxygen evolution. Nat. Commun., 2023, 14 1811

[15]	Hua DX, Huang JZ, Fabbri E, et al. . Development of anion exchange membrane water electrolysis and the associated challenges: a review. ChemElectroChem, 2023, 10 e202200999

[16]	Wijaya GHA, Im KS, Nam SY. Advancements in commercial anion exchange membranes: a review of membrane properties in water electrolysis applications. Desalin. Water Treat., 2024, 320 100605

[17]	Yin LQ, Ren R, He LL, et al. . Stable anion exchange membrane bearing quinuclidinium for high-performance water electrolysis. Angew. Chem. Int. Ed., 2024, 63 e202400764

[18]	Du NY, Roy C, Peach R, et al. . Anion-exchange membrane water electrolyzers. Chem. Rev., 2022, 122: 11830-11895

[19]	Chen NJ, Lee YM. Anion exchange polyelectrolytes for membranes and ionomers. Prog. Polym. Sci., 2021, 113 101345

[20]	Ponce-González J, Whelligan DK, Wang LQ, et al. . High performance aliphatic-heterocyclic benzyl-quaternary ammonium radiation-grafted anion-exchange membranes. Energy Environ. Sci., 2016, 9: 3724-3735

[21]	Lin CX, Huang XL, Guo D, et al. . Side-chain-type anion exchange membranes bearing pendant quaternary ammonium groups via flexible spacers for fuel cells. J. Mater. Chem. A, 2016, 4: 13938-13948

[22]	Lin CX, Yu DM, Wang JX, et al. . Facile construction of poly(arylene ether)s-based anion exchange membranes bearing pendent N-spirocyclic quaternary ammonium for fuel cells. Int. J. Hydrog. Energy, 2019, 44: 26565-26576

[23]	Changkhamchom S, Kunanupatham P, Phasuksom K, et al. . Anion exchange membranes composed of quaternized polybenzimidazole and quaternized graphene oxide for glucose fuel cell. Int. J. Hydrog. Energy, 2021, 46: 5642-5652

[24]	Tuli SK, Roy AL, Elgammal RA, et al. . Polystyrene-based anion exchange membranes via click chemistry: improved properties and AEM performance. Polym. Int., 2018, 67: 1302-1312

[25]	Park HJ, Lee SY, Lee TK, et al. . N3-butyl imidazolium-based anion exchange membranes blended with poly(vinyl alcohol) for alkaline water electrolysis. J. Membr. Sci., 2020, 611 118355

[26]	Qian JF, Zheng H, Chen KX, et al. . Highly conductive and stable anion exchange membranes with dense flexible alkyl ether linkages and 1,2,4,5-tetramethylimidazolium for water electrolysis. J. Membr. Sci., 2024, 701 122745

[27]	Wang JJ, He GH, Wu XM, et al. . Crosslinked poly (ether ether ketone) hydroxide exchange membranes with improved conductivity. J. Membr. Sci., 2014, 459: 86-95

[28]	Xue BX, Wang F, Zheng JF, et al. . Highly stable polysulfone anion exchange membranes incorporated with bulky alkyl substituted guanidinium cations. Mol. Syst. Des. Eng., 2019, 4: 1039-1047

[29]	Zhong RY, Wang Q, Du L, et al. . Ultrathin polycrystalline Co₃O₄ nanosheets with enriched oxygen vacancies for efficient electrochemical oxygen evolution and 5-hydroxymethylfurfural oxidation. Appl. Surf. Sci., 2022, 584 152553

[30]	Emmanuel K, Cheng CL, Mondal AN, et al. . Covalently cross-linked pyridinium based AEMs with aromatic pendant groups for acid recovery via diffusion dialysis. Sep. Purif. Technol., 2016, 164: 125-131

[31]	Ayaz S, Yao ZY, Yang Y, et al. . Chemically stable anion exchange membrane with 2, 6-protected pendant pyridinium cation for alkaline fuel cell. J. Membr. Sci., 2023, 680 121736

[32]	Wu XY, Chen NJ, Hu C, et al. . Fluorinated poly(aryl piperidinium) membranes for anion exchange membrane fuel cells. Adv. Mater., 2023, 35 2210432

[33]	Zhang ZJ, Yu N, Sun HR, et al. . New anion exchange membranes based on long side-chain piperidinium cation grafted poly(ether ketone-cardo). Eur. Polym. J., 2023, 195 112212

[34]	Pham TH, Jannasch P. Aromatic polymers incorporating bis-N-spirocyclic quaternary ammonium moieties for anion-exchange membranes. ACS Macro Lett., 2015, 4: 1370-1375

[35]	Shang LC, Yao D, Pang BH, et al. . Anion exchange membranes based on poly (ether ether ketone) containing N-spirocyclic quaternary ammonium cations in phenyl side chain. Int. J. Hydrog. Energy, 2021, 46: 19116-19128

[36]	An L, Yang F, Fu CH, et al. . A functionally stable RuMn electrocatalyst for oxygen evolution reaction in acid. Adv. Funct. Mater., 2022, 32: 2200131

[37]	Lin CX, Zhuo YZ, Lai AN, et al. . Side-chain-type anion exchange membranes bearing pendent imidazolium-functionalized poly(phenylene oxide) for fuel cells. J. Membr. Sci., 2016, 513: 206-216

[38]	Wu XM, Chen WT, Yan XM, et al. . Enhancement of hydroxide conductivity by the di-quaternization strategy for poly(ether ether ketone) based anion exchange membranes. J. Mater. Chem. A, 2014, 2: 12222-12231

[39]	Qi L, Wang X, Chao G, et al. . Enhancement in the alkaline stability of poly(arylene ether ketone)-typed anion-exchange membranes via phenylene piperidinium blocks. J. Membr. Sci., 2023, 687 122057

[40]	Han JJ, Peng HQ, Pan J, et al. . Highly stable alkaline polymer electrolyte based on a poly(ether ether ketone) backbone. ACS Appl. Mater. Interfaces, 2013, 5: 13405-13411

[41]	Serbanescu OS, Voicu SI, Thakur VK. Polysulfone functionalized membranes: properties and challenges. Mater. Today Chem., 2020, 17 100302

[42]	Han KW, Ko KH, Abu-Hakmeh K, et al. . Molecular dynamics simulation study of a polysulfone-based anion exchange membrane in comparison with the proton exchange membrane. J. Phys. Chem. C, 2014, 118: 12577-12587

[43]	Pan Y, Zhang QD, Yan XM, et al. . Hydrophilic side chain assisting continuous ion-conducting channels for anion exchange membranes. J. Membr. Sci., 2018, 552: 286-294

[44]	Guo ML, Wang ZH, Xu YF, et al. . Vinyl-based in-situ crosslinked polybenzimidazoles for anion exchange membranes water electrolysis. J. Membr. Sci., 2024, 707 123026

[45]	Gui QL, Ouyang Q, Xu CR, et al. . Facile and safe synthesis of novel self-pored amine-functionalized polystyrene with nanoscale bicontinuous morphology. Int. J. Mol. Sci., 2020, 21 9404

[46]	Liang YM, Wang FL, Cai R, et al. . Activating ion transport channels of poly(styrene-b-(ethylene-co-butylene)-b-styrene) anion exchange membranes using ionic oligomeric polystyrene. Int. J. Hydrogen Energy, 2024, 69: 1439-1449

[47]	Liu WC, Liu L, Liao JY, et al. . Self-crosslinking of comb-shaped polystyrene anion exchange membranes for alkaline fuel cell application. J. Membr. Sci., 2017, 536: 133-140

[48]	Yuan CL, Li P, Zeng LP, et al. . Poly(vinyl alcohol)-based hydrogel anion exchange membranes for alkaline fuel cell. Macromolecules, 2021, 54: 7900-7909

[49]	Chen S, Wang CL, Gao FY, et al. . An indium-induced-synthesis In_0.17Ru_0.83O₂ nanoribbon as highly active electrocatalyst for oxygen evolution in acidic media at high current densities above 400 mA cm^–2. J. Mater. Chem. A, 2022, 10: 3722-3731

[50]	Varcoe JR, Atanassov P, Dekel DR, et al. . Anion-exchange membranes in electrochemical energy systems. Energy Environ. Sci., 2014, 7: 3135-3191

[51]	Zhu L, Peng X, Shang SL, et al. . High performance anion exchange membrane fuel cells enabled by fluoropoly(olefin) membranes. Adv. Funct. Mater., 2019, 29: 1902059

[52]	Wang C, Mo BM, He ZF, et al. . Crosslinked norbornene copolymer anion exchange membrane for fuel cells. J. Membr. Sci., 2018, 556: 118-125

[53]	Zheng WT, He LL, Tang T, et al. . Poly(dibenzothiophene-terphenyl piperidinium) for high-performance anion exchange membrane water electrolysis. Angew. Chem. Int. Ed., 2024, 63 e202405738

[54]	Li LM, Cheng ZF, Su JQ, et al. . One-dimensional amorphous porous iridium–ruthenium oxide for efficient acidic oxygen evolution reaction. J. Mater. Chem. A, 2023, 11: 25268-25274

[55]	Liu L, Ma HY, Khan M, et al. . Recent advances and challenges in anion exchange membranes development/application for water electrolysis: a review. Membranes, 2024, 14 85

[56]	Pavel CC, Cecconi F, Emiliani C, et al. . Highly efficient platinum group metal free based membrane-electrode assembly for anion exchange membrane water electrolysis. Angew. Chem. Int. Ed., 2014, 53: 1378-1381

[57]	Cho MK, Park HY, Choe S, et al. . Factors in electrode fabrication for performance enhancement of anion exchange membrane water electrolysis. J. Power. Sources, 2017, 347: 283-290

[58]	Vincent I, Kruger A, Bessarabov D. Development of efficient membrane electrode assembly for low cost hydrogen production by anion exchange membrane electrolysis. Int. J. Hydrog. Energy, 2017, 42: 10752-10761

[59]	Park JE, Kang SY, Oh SH, et al. . High-performance anion-exchange membrane water electrolysis. Electrochim. Acta, 2019, 295: 99-106

[60]	Ng WK, Wong WY, Rosli NAH, et al. . Commercial anion exchange membranes (AEMs) for fuel cell and water electrolyzer applications: performance, durability, and materials advancement. Separations, 2023, 10 424

[61]	Fuel Cell Technologies Office, U.S. Department of Energy: Multi-Year Program Plan. (2024) https://www.energy.gov/eere/fuelcells/hydrogen-and-fuel-cell-technologies-office-multi-year-program-plan. Accessed 8 Jan 2026

[62]	Vinodh R, Kalanur SS, Natarajan SK, et al. . Recent advancements of polymeric membranes in anion exchange membrane water electrolyzer (AEMWE): a critical review. Polymers, 2023, 15 2144

[63]	Duan QJ, Ge SH, Wang CY. Water uptake, ionic conductivity and swelling properties of anion-exchange membrane. J. Power. Sources, 2013, 243: 773-778

[64]	Peng J, Roy AL, Greenbaum SG, et al. . Effect of CO₂ absorption on ion and water mobility in an anion exchange membrane. J. Power. Sources, 2018, 380: 64-75

[65]	Lo Vecchio C, Carbone A, Gatto I, et al. . Investigation of fumasep® FAA3-50 membranes in alkaline direct methanol fuel cells. Polymers, 2023, 15: 1555

[66]	Tham DD, Kim D. C2 and N3 substituted imidazolium functionalized poly(arylene ether ketone) anion exchange membrane for water electrolysis with improved chemical stability. J. Membr. Sci., 2019, 581: 139-149

[67]	Konovalova A, Kim H, Kim S, et al. . Blend membranes of polybenzimidazole and an anion exchange ionomer (FAA3) for alkaline water electrolysis: improved alkaline stability and conductivity. J. Membr. Sci., 2018, 564: 653-662

[68]	Kaczur JJ, Yang HZ, Liu ZC, et al. . Carbon dioxide and water electrolysis using new alkaline stable anion membranes. Front. Chem., 2018, 6 263

[69]	Lee WH, Park EJ, Han J, et al. . Poly(terphenylene) anion exchange membranes: the effect of backbone structure on morphology and membrane property. ACS Macro Lett., 2017, 6: 566-570

[70]	Endrődi B, Kecsenovity E, Samu A, et al. . High carbonate ion conductance of a robust PiperION membrane allows industrial current density and conversion in a zero-gap carbon dioxide electrolyzer cell. Energy Environ. Sci., 2020, 13: 4098-4105

[71]	Khataee A, Shirole A, Jannasch P, et al. . Anion exchange membrane water electrolysis using Aemion™ membranes and nickel electrodes. J. Mater. Chem. A, 2022, 10: 16061-16070

[72]	Hu KW, Fang JK, Ai XM, et al. . Comparative study of alkaline water electrolysis, proton exchange membrane water electrolysis and solid oxide electrolysis through multiphysics modeling. Appl. Energy, 2022, 312 118788

[73]	Hugar KM, You W, Coates GW. Protocol for the quantitative assessment of organic cation stability for polymer electrolytes. ACS Energy Lett., 2019, 4: 1681-1686

[74]	Marino MG, Kreuer KD. Alkaline stability of quaternary ammonium cations for alkaline fuel cell membranes and ionic liquids. Chemsuschem, 2015, 8: 513-523

[75]	Henkensmeier D, Cho WC, Jannasch P, et al. . Separators and membranes for advanced alkaline water electrolysis. Chem. Rev., 2024, 124: 6393-6443

[76]	Henkensmeier D, Najibah M, Harms C, et al. . Overview: state-of-the art commercial membranes for anion exchange membrane water electrolysis. J. Electrochem. Energy Convers. Storage, 2021, 18 024001

[77]	Skulimowska A, Dupont M, Zaton M, et al. . Proton exchange membrane water electrolysis with short-side-chain Aquivion® membrane and IrO₂ anode catalyst. Int. J. Hydrogen Energy, 2014, 39: 6307-6316

[78]	Henkensmeier D, Cho HR, Kim HJ, et al. . Polybenzimidazolium hydroxides:structure, stability and degradation. Polym. Degrad. Stab., 2012, 97: 264-272

[79]	Germer W, Leppin J, Nunes Kirchner C, et al. . Phase separated methylated polybenzimidazole (O-PBI) based anion exchange membranes. Macromol. Mater. Eng., 2015, 300: 497-509

[80]	Wright AG, Holdcroft S. Hydroxide-stable ionenes. ACS Macro Lett., 2014, 3: 444-447

[81]	Wright AG, Fan JT, Britton B, et al. . Hexamethyl-p-terphenyl poly(benzimidazolium): a universal hydroxide-conducting polymer for energy conversion devices. Energy Environ. Sci., 2016, 9: 2130-2142

[82]	Fan JT, Willdorf-Cohen S, Schibli EM, et al. . Poly(bis-arylimidazoliums) possessing high hydroxide ion exchange capacity and high alkaline stability. Nat. Commun., 2019, 10 2306

[83]	Moreno-González M, Mardle P, Zhu S, et al. . One year operation of an anion exchange membrane water electrolyzer utilizing Aemion+® membrane: minimal degradation, low H₂ crossover and high efficiency. J. Power Sources Adv., 2023, 19 100109

[84]	Lee WH, Kim YS, Bae C. Robust hydroxide ion conducting poly(biphenyl alkylene)s for alkaline fuel cell membranes. ACS Macro Lett., 2015, 4: 814-818

[85]	Olsson JS, Pham TH, Jannasch P. Poly(arylene piperidinium) hydroxide ion exchange membranes: synthesis, alkaline stability, and conductivity. Adv. Funct. Mater., 2018, 28 1702758

[86]	Chen NJ, Wang HH, Kim SP, et al. . Poly(fluorenyl aryl piperidinium) membranes and ionomers for anion exchange membrane fuel cells. Nat. Commun., 2021, 12 2367

[87]	Chen NJ, Jiang Q, Song F, et al. . Robust piperidinium-enriched polystyrene ionomers for anion exchange membrane fuel cells and water electrolyzers. ACS Energy Lett., 2023, 8: 4043-4051

[88]	Kutz RB, Chen QM, Yang HZ, et al. . Sustainion imidazolium-functionalized polymers for carbon dioxide electrolysis. Energy Technol., 2017, 5: 929-936

[89]	Meek KM, Reed CM, Pivovar B, et al. . The alkali degradation of LDPE-based radiation-grafted anion-exchange membranes studied using different ex situ methods. RSC Adv., 2020, 10: 36467-36477

[90]	Li DG, Motz AR, Bae C, et al. . Durability of anion exchange membrane water electrolyzers. Energy Environ. Sci., 2021, 14: 3393-3419

[91]	Lee J, Min K, Jeon S, et al. . Development of crosslinked SEBS-based anion exchange membranes for water electrolysis: investigation of the crosslinker effect. Int. J. Hydrog. Energy, 2023, 48: 24180-24195

[92]	Shi Y, Zhao ZF, Liu W, et al. . Physically self-cross-linked SEBS anion exchange membranes. Energy Fuels, 2020, 34: 16746-16755

[93]	Mohanty AD, Tignor SE, Krause JA, et al. . Systematic alkaline stability study of polymer backbones for anion exchange membrane applications. Macromolecules, 2016, 49: 3361-3372

[94]	Fang ZY, Ye C, Ling T, et al. . Stability challenges of anion-exchange membrane water electrolyzers from components to integration level. Chem Catalysis, 2024, 4 101145

[95]	Hagesteijn KFL, Jiang SX, Ladewig BP. A review of the synthesis and characterization of anion exchange membranes. J. Mater. Sci., 2018, 53: 11131-11150

[96]	Mustain WE, Chatenet M, Page M, et al. . Durability challenges of anion exchange membrane fuel cells. Energy Environ. Sci., 2020, 13: 2805-2838

[97]	Arges CG, Zhang L. Anion exchange membranes’ evolution toward high hydroxide ion conductivity and alkaline resiliency. ACS Appl. Energy Mater., 2018, 1: 2991-3012

[98]	Lee B, Yun D, Lee JS, et al. . Development of highly alkaline stable OH^–-conductors based on imidazolium cations with various substituents for anion exchange membrane-based alkaline fuel cells. J. Phys. Chem. C, 2019, 123: 13508-13518

[99]	Liu Y, Wang JH, Yang Y, et al. . Anion transport in a chemically stable, sterically bulky α-C modified imidazolium functionalized anion exchange membrane. J. Phys. Chem. C, 2014, 118: 15136-15145

[100]

Long H, Pivovar B. Hydroxide degradation pathways for imidazolium cations: a DFT study. J. Phys. Chem. C, 2014, 118: 9880-9888

[101]

Holdcroft S, Fan JT. Sterically-encumbered ionenes as hydroxide ion-conducting polymer membranes. Curr. Opin. Electrochem., 2019, 18: 99-105

[102]

Maurya S, Shin SH, Kim Y, et al. . A review on recent developments of anion exchange membranes for fuel cells and redox flow batteries. RSC Adv., 2015, 5: 37206-37230

[103]

Hugar KM, Kostalik HAIVCoates GW. Imidazolium cations with exceptional alkaline stability: a systematic study of structure–stability relationships. J. Am. Chem. Soc., 2015, 137: 8730-8737

[104]

Amel A, Zhu L, Hickner M, et al. . Influence of sulfone linkage on the stability of aromatic quaternary ammonium polymers for alkaline fuel cells. J. Electrochem. Soc., 2014, 161: F615-F621

[105]

Choe YK, Fujimoto C, Lee KS, et al. . Alkaline stability of benzyl trimethyl ammonium functionalized polyaromatics: a computational and experimental study. Chem. Mater., 2014, 26: 5675-5682

[106]

Fujimoto C, Kim DS, Hibbs M, et al. . Backbone stability of quaternized polyaromatics for alkaline membrane fuel cells. J. Membr. Sci., 2012, 423: 438-449

[107]

Park EJ, Kim YS. Quaternized aryl ether-free polyaromatics for alkaline membrane fuel cells: synthesis, properties, and performance–a topical review. J. Mater. Chem. A, 2018, 6: 15456-15477

[108]

Arges CG, Ramani V. Two-dimensional NMR spectroscopy reveals cation-triggered backbone degradation in polysulfone-based anion exchange membranes. Proc. Natl. Acad. Sci. U. S. A., 2013, 110: 2490-2495

[109]

Kang SY, Park JE, Jang GY, et al. . High-performance and durable water electrolysis using a highly conductive and stable anion-exchange membrane. Int. J. Hydrog. Energy, 2022, 47: 9115-9126

[110]

Cheng X, Li CH, Zou XW, et al. . Highly conductive alkoxy chain cross-linked poly (aryl piperidinium) anion exchange membrane for water electrolysis. Chem. Eng. J., 2024, 483 149328

[111]

Hu C, Kang NY, Kang HW, et al. . Triptycene branched poly(aryl-co-aryl piperidinium) electrolytes for alkaline anion exchange membrane fuel cells and water electrolyzers. Angew. Chem. Int. Ed., 2024, 63 e202316697

[112]

Hu C, Zhang QG, Lin CX, et al. . Multi-cation crosslinked anion exchange membranes from microporous Tröger’s base copolymers. J. Mater. Chem. A, 2018, 6: 13302-13311

[113]

Ma YC, Hu C, Yi GQ, et al. . Durable multiblock poly(biphenyl alkylene) anion exchange membranes with microphase separation for hydrogen energy conversion. Angew. Chem. Int. Ed., 2023, 62 e202311509

[114]

Wang XQ, Thomas AM, Lammertink RGH. Dimensionally stable anion exchange membranes based on macromolecular-cross-linked poly(arylene piperidinium) for water electrolysis. ACS Appl. Mater. Interfaces, 2024, 16: 2593-2605

[115]

Wu ML, Zhang X, Zhao Y, et al. . A high-performance hydroxide exchange membrane enabled by Cu²⁺-crosslinked chitosan. Nat. Nanotechnol., 2022, 17: 629-636

[116]

Cheng X, Li CH, Zou XW, et al. . Multi-cation alkoxy chains with high ion conductivity and durability in cross-linked poly (aryl piperidinium) anion exchange membranes. Sep. Purif. Technol., 2024, 345 127418

[117]

Chen HH, Bang KT, Tian Y, et al. . Poly(ethylene piperidinium)s for anion exchange membranes. Angew. Chem. Int. Ed., 2023, 62 e202307690

[118]

Li XF, Yang K, Wang ZM, et al. . Chain architecture dependence of morphology and water transport in poly(fluorene alkylene)-based anion-exchange membranes. Macromolecules, 2022, 55: 10607-10617

[119]

Zhang XZ, Yu ZX, Tang JL, et al. . Mxenes as inorganic fillers for the construction of poly(aryl piperidinium) anion exchange membranes with microphase separation structures to enhance ionic conductivity. Fuel, 2024, 365 131177

[120]

Deng GX, Liao YW, Lin YK, et al. . Engineering robust triazine crosslinked and pyridine capped anion exchange membrane for advanced water electrolysis. Angew. Chem.-Int. Edit., 2024, 63 e202412632

[121]

Wang XQ, Fang ZY, Zhang M, et al. . Macromolecular crosslinked poly(aryl piperidinium)-based anion exchange membranes with enhanced ion conduction for water electrolysis. J. Membr. Sci., 2024, 700 122717

[122]

Kim Y, Wang YM, France-Lanord A, et al. . Ionic highways from covalent assembly in highly conducting and stable anion exchange membrane fuel cells. J. Am. Chem. Soc., 2019, 141: 18152-18159

[123]

Zhang JL, Pan J, Yuan YJ, et al. . In-situ gradient cross-linking in anion exchange membranes for water electrolyzers. Chem. Mater., 2024, 36: 5720-5729

[124]

Yang ZJ, Zhou JH, Wang SW, et al. . A strategy to construct alkali-stable anion exchange membranes bearing ammonium groups via flexible spacers. J. Mater. Chem. A, 2015, 3: 15015-15019

[125]

Zhang Y, Chen WT, Yan XM, et al. . Ether spaced N-spirocyclic quaternary ammonium functionalized crosslinked polysulfone for high alkaline stable anion exchange membranes. J. Membr. Sci., 2020, 598 117650

[126]

Hou JQ, Wang XY, Liu YZ, et al. . Wittig reaction constructed an alkaline stable anion exchange membrane. J. Membr. Sci., 2016, 518: 282-288

[127]

Dang HS, Weiber EA, Jannasch P. Poly(phenylene oxide) functionalized with quaternary ammonium groups via flexible alkyl spacers for high-performance anion exchange membranes. J. Mater. Chem. A, 2015, 3: 5280-5284

[128]

Ma YC, Li LJ, You XQ, et al. . Poly(fluorenyl alkylene)-based anion exchange membranes for high-performance water electrolysis. Chem. Eng. J., 2024, 480 148225

[129]

Cha MS, Park JE, Kim S, et al. . Poly(carbazole)-based anion-conducting materials with high performance and durability for energy conversion devices. Energy Environ. Sci., 2020, 13: 3633-3645

[130]

Tanaka M, Fukasawa K, Nishino E, et al. . Anion conductive block poly(arylene ether)s: synthesis, properties, and application in alkaline fuel cells. J. Am. Chem. Soc., 2011, 133: 10646-10654

[131]

He R, Wen PS, Zhang HN, et al. . In-situ photocrosslinked hydroxide conductive membranes based on photosensitive poly(arylene ether sulfone) block copolymers for anion exchange membrane fuel cells. J. Membr. Sci., 2018, 556: 73-84

[132]

Liu X, Xie N, Xue JD, et al. . Magnetic-field-oriented mixed-valence-stabilized ferrocenium anion-exchange membranes for fuel cells. Nat. Energy, 2022, 7: 329-339

[133]

Chen XM, Zhan YQ, Tang JL, et al. . Advances in high performance anion exchange membranes: molecular design, preparation methods, and ion transport dynamics. J. Environ. Chem. Eng., 2023, 11 110749

[134]

Hosseini SM, Jeddi F, Nemati M, et al. . Electrodialysis heterogeneous anion exchange membrane modified by PANI/MWCNT composite nanoparticles: preparation, characterization and ionic transport property in desalination. Desalination, 2014, 341: 107-114

[135]

Wang HS, Zeng GY, Yang ZM, et al. . Nanofiltration membrane based on a dual-reinforcement strategy of support and selective layers for efficient Mg²⁺/Li⁺ separation. Sep. Purif. Technol., 2024, 330 125254

[136]

Wang JH, Zhao Y, Setzler BP, et al. . Poly(aryl piperidinium) membranes and ionomers for hydroxide exchange membrane fuel cells. Nat. Energy, 2019, 4: 392-398

[137]

Lim H, Jeong JY, Shin G, et al. . Realizing superior durability of water electrolyzer using anion exchange membrane with an interstitial alkyl chain: from a single cell to large-sized 1-cell stack. Adv. Energy Mater., 2024, 14: 2401725

[138]

Tao ZW, Wang CY, Zhao XY, et al. . Progress in high-performance anion exchange membranes based on the design of stable cations for alkaline fuel cells. Adv. Mater. Technol., 2021, 6 2001220

[139]

Lu JH, Wang Y, Li JS, et al. . Design of polymer structure with “multi cationic sites” achieves high conductivity and robustness of anion exchange membranes. J. Power. Sources, 2024, 624 235577

[140]

Gu FL, Dong HL, Li YY, et al. . Base stable pyrrolidinium cations for alkaline anion exchange membrane applications. Macromolecules, 2014, 47: 6740-6747

[141]

Koronka D, Miyatake K. Anion exchange membranes containing no β-hydrogen atoms on ammonium groups: synthesis, properties, and alkaline stability. RSC Adv., 2021, 11: 1030-1038

[142]

Liu FH, Miyatake K, Tanabe M, et al. . High-performance anion exchange membrane water electrolyzers enabled by highly gas permeable and dimensionally stable anion exchange ionomers. Adv. Sci., 2024, 11: 2402969

[143]

Zhang SH, Ma WL, Tian L, et al. . Twisted poly(p-terphenyl-co-m-terphenyl)-based anion exchange membrane for water electrolysis. ACS Appl. Mater. Interfaces, 2024, 16: 7660-7669

[144]

Yang JY, Zhao JL, Li N, et al. . Carbazole-based branched poly(aryl piperidinium) membranes for ultra-stable anion exchange membrane fuel cells. Chem. Eng. J., 2024, 489 151446

[145]

Liu L, Ma WZ, Zhang JJ, et al. . The design and synthesis of a long-side-chain-type anion exchange membrane with a hydrophilic spacer for alkaline fuel cells. J. Membr. Sci., 2023, 678 121663

[146]

Chen HH, Tao R, Bang KT, et al. . Anion exchange membranes for fuel cells: state-of-the-art and perspectives. Adv. Energy Mater., 2022, 12: 2200934

[147]

Hibbs MR, Fujimoto CH, Cornelius CJ. Synthesis and characterization of poly(phenylene)-based anion exchange membranes for alkaline fuel cells. Macromolecules, 2009, 42: 8316-8321

[148]

Hibbs MR. Alkaline stability of poly(phenylene)-based anion exchange membranes with various cations. J. Polym. Sci. Part B Polym. Phys., 2013, 51: 1736-1742

[149]

Yokota N, Shimada M, Ono H, et al. . Aromatic copolymers containing ammonium-functionalized oligophenylene moieties as highly anion conductive membranes. Macromolecules, 2014, 47: 8238-8246

[150]

Feng ZM, Gupta G, Mamlouk M. A review of anion exchange membranes prepared via Friedel-Crafts reaction for fuel cell and water electrolysis. Int. J. Hydrog. Energy, 2023, 48: 25830-25858

[151]

Zhou A, Guo WJ, Wang YQ, et al. . The rapid preparation of efficient MoFeCo-based bifunctional electrocatalysts via Joule Heating for overall water splitting. Electrochemistry, 2022, 28: 2214007

[152]

Xie XH, Du L, Yan LT, et al. . Oxygen evolution reaction in alkaline environment: material challenges and solutions. Adv. Funct. Mater., 2022, 32 2110036

[153]

Ni J, Shi ZP, Wang X, et al. . Recent development of low iridium electrocatalysts toward efficient water oxidation. J. Electrochem., 2022, 28: 2214010

[154]

Browne MP, Nolan H, Duesberg GS, et al. . Low-overpotential high-activity mixed manganese and ruthenium oxide electrocatalysts for oxygen evolution reaction in alkaline media. ACS Catal., 2016, 6: 2408-2415

[155]

Jia SY, Zhang JC, Liu QC, et al. . Competitive adsorption of oxygen-containing intermediates on ruthenium–tin solid-solution oxides for alkaline oxygen evolution. J. Mater. Chem. A, 2023, 11: 23489-23497

[156]

Che YC, Zhang XX, Bo SW, et al. . High-entropy ruthenium-based oxides with rich grain boundaries for efficient oxygen evolution. ACS Mater. Lett., 2024, 6: 4142-4148

[157]

Zhao DK, Zhu YG, Wu QK, et al. . Low-loading Ir decorated cobalt encapsulated N-doped carbon nanotubes/porous carbon sheet implements efficient hydrogen/oxygen trifunctional electrocatalysis. Chem. Eng. J., 2022, 430 132825

[158]

Zhang ZQ, Xia Y, Ye M, et al. . Low Ir-content Ir/Fe@NCNT bifunctional catalyst for efficient water splitting. Int. J. Hydrog. Energy, 2022, 47: 13371-13385

[159]

Yang NW, Tian SN, Feng YJ, et al. . Introducing high-valence iridium single atoms into bimetal phosphides toward high-efficiency oxygen evolution and overall water splitting. Small, 2023, 19 2207253

[160]

Wen N, Xia YG, Wang HH, et al. . Large-scale synthesis of spinel Ni_xMn_3-_xO₄ solid solution immobilized with iridium single atoms for efficient alkaline seawater electrolysis. Adv. Sci., 2022, 9 2200529

[161]

Porokhin SV, Nikitina VA, Aksyonov DA, et al. . Mixed-cation perovskite La_0.6Ca_0.4Fe_0.7Ni_0.3O_2.9 as a stable and efficient catalyst for the oxygen evolution reaction. ACS Catal., 2021, 11: 8338-8348

[162]

Dong FF, Li L, Kong ZQ, et al. . Materials engineering in perovskite for optimized oxygen evolution electrocatalysis in alkaline condition. Small, 2021, 17 2006638

[163]

Dadvari P, Hung WH, Wang KW. High entropy spinel oxide (AlCrCoNiFe₂)O as highly active oxygen evolution reaction catalysts. ACS Omega, 2024, 9: 27692-27698

[164]

Sharma L, Katiyar NK, Parui A, et al. . Low-cost high entropy alloy (HEA) for high-efficiency oxygen evolution reaction (OER). Nano Res., 2022, 15: 4799-4806

[165]

Zhang ZJ, Guo JP, Sun SH, et al. . Optimized valence state of Co and Ni in high-entropy alloy for high active-stable OER. Rare Met., 2023, 42: 3607-3613

[166]

Ali Ehsan M, Khan A, Hakeem AS. Binary CoNi and ternary FeCoNi alloy thin films as high-performance and stable electrocatalysts for oxygen evolution reaction. ACS Appl. Energy Mater., 2023, 6: 9556-9567

[167]

Mei YJ, Feng YB, Zhang CX, et al. . High-entropy alloy with Mo-coordination as efficient electrocatalyst for oxygen evolution reaction. ACS Catal., 2022, 12: 10808-10817

[168]

Guo DD, Yu HM, Chi J, et al. . Self-supporting NiFe LDHs@Co-OH-CO₃ nanorod array electrode for alkaline anion exchange membrane water electrolyzer. J. Electrochem., 2022, 28: 2214003

[169]

Li LF, Long JX, Ye QL, et al. . Ni-Co layered double-hydroxide arrays on stainless steel substrate: interfacial hydroxide layer enhanced electrocatalyst with high stability for oxygen evolution reaction in alkaline media. J. Alloys Compd., 2023, 946 169325

[170]

Cai ZY, Shen J, Zhang MZ, et al. . Cu_xO nanorod arrays shelled with CoNi layered double hydroxide nanosheets for enhanced oxygen evolution reaction under alkaline conditions. J. Colloid Interface Sci., 2023, 630: 57-65

[171]

Ding YR, Wang ZY, Liang ZJ, et al. . A monolayer high-entropy layered hydroxide frame for efficient oxygen evolution reaction. Adv. Mater., 2025, 37 2302860

[172]

Liu D, Yan XX, Guo PF, et al. . Inert Mg incorporation to break the activity/stability relationship in high-entropy layered hydroxides for the electrocatalytic oxygen evolution reaction. ACS Catal., 2023, 13: 7698-7706

[173]

Zhou BW, Wang JP, Guo LF, et al. . Microwave-assisted PtRu alloying on defective tungsten oxide: a pathway to improved hydroxyl dynamics for highly-efficient hydrogen evolution reaction. Adv. Energy Mater., 2024, 14 2402372

[174]

Kuang PY, Ni ZR, Zhu BC, et al. . Modulating the d-band center enables ultrafine Pt₃Fe alloy nanoparticles for pH-universal hydrogen evolution reaction. Adv. Mater., 2023, 35 2303030

[175]

Zheng YX, Shang PF, Pei F, et al. . Achieving an efficient hydrogen evolution reaction with a bicontinuous nanoporous PtNiMg alloy of ultralow noble-metal content at an ultrawide range of current densities. Chem. Eng. J., 2022, 433 134571

[176]

Zhang WY, Huang BL, Wang K, et al. . WO_x-surface decorated PtNi@Pt dendritic nanowires as efficient pH-universal hydrogen evolution electrocatalysts. Adv. Energy Mater., 2021, 11 2003192

[177]

Yang WW, Cheng P, Li Z, et al. . Tuning the cobalt–platinum alloy regulating single-atom platinum for highly efficient hydrogen evolution reaction. Adv. Funct. Mater., 2022, 32 2205920

[178]

Ma HC, Peng W, Wong H, et al. . Anchoring ultralow platinum by harnessing atomic defects derived from self-reconstruction for alkaline hydrogen evolution reaction. Adv. Funct. Mater., 2024, 34 2409575

[179]

Jiao JX, Chen D, Zhao HY, et al. . Oxygen octahedral void-confined iodine single-site RuO₂ catalysts for water reduction. Appl. Catal. B Environ. Energy, 2025, 361 124650

[180]

Yang JH, Yang SX, An LL, et al. . Strain-engineered Ru-NiCr LDH nanosheets boosting alkaline hydrogen evolution reaction. ACS Catal., 2024, 14: 3466-3474

[181]

Hong YJ, Jeong S, Seol JH, et al. . Ru₂P/Ir₂P heterostructure promotes hydrogen spillover for efficient alkaline hydrogen evolution reaction. Adv. Energy Mater., 2024, 14 2401426

[182]

Zhou CH, Shi J, Dong ZQ, et al. . Oxophilic gallium single atoms bridged ruthenium clusters for practical anion-exchange membrane electrolyzer. Nat. Commun., 2024, 15 6741

[183]

Cai LB, Bai HY, Kao CW, et al. . Platinum–ruthenium dual-atomic sites dispersed in nanoporous Ni0_8.5Se enabling ampere-level current density hydrogen production. Small, 2024, 20: 2311178

[184]

Luo H, Li L, Lin FX, et al. . Sub-2 nm microstrained high-entropy-alloy nanoparticles boost hydrogen electrocatalysis. Adv. Mater., 2024, 36 2403674

[185]

Lu F, Zhou M, Zhou YX, et al. . First-row transition metal based catalysts for the oxygen evolution reaction under alkaline conditions: Basic principles and recent advances. Small, 2017, 13: 1701931

[186]

Peng C, Li JY, Shi LX, et al. . Electrochemically activated metal oxide sites at Rh–Ni2P electrocatalyst for efficient alkaline hydrogen evolution reaction. Rare Met., 2024, 43: 6416-6425

[187]

Li RC, Hu BH, Yu TW, et al. . New TiO₂-based oxide for catalyzing alkaline hydrogen evolution reaction with noble metal-like performance. Small Methods, 2021, 5 2100246

[188]

Sun HM, Yao BC, Han YX, et al. . Multi-interface engineering of self-supported nickel/yttrium oxide electrode enables kinetically accelerated and ultra-stable alkaline hydrogen evolution at industrial-level current density. Adv. Energy Mater., 2024, 14 2303563

[189]

Xu W, Ni XM, Zhang LJ, et al. . Tuning the electronic structure of tungsten oxide for enhanced hydrogen evolution reaction in alkaline electrolyte. ChemElectroChem, 2022, 9 e202101300

[190]

Qian YT, Sun Y, Zhang FF, et al. . In situ construction of layered transition metal phosphides/sulfides heterostructures for efficient hydrogen evolution in acidic and alkaline media. Chem. Eng. J., 2024, 490 151693

[191]

Luo QM, Zhao YW, Sun L, et al. . Interface oxygen vacancy enhanced alkaline hydrogen evolution activity of cobalt-iron phosphide/CeO₂ hollow nanorods. Chem. Eng. J., 2022, 437 135376

[192]

Gao QS, Wang ZS, Gao W, et al. . NiFeCo-based high entropy alloys nanoparticles coated with N-doped graphene layers as hydrogen evolution catalyst in alkaline solution. Chem. Eng. J., 2024, 489 151370

[193]

Li DY, Wang JK, Wang SH, et al. . An interface engineering induced hierarchical NiCo/V₂O₃/C Schottky heterojunction catalyst for large-current-density hydrogen evolution reaction. J. Mater. Chem. A, 2023, 11: 23397-23404

[194]

Maurya S, Noh S, Matanovic I, et al. . Rational design of polyaromatic ionomers for alkaline membrane fuel cells with >1 W cm⁻² power density. Energy Environ. Sci., 2018, 11: 3283-3291

[195]

Lin N, Zausch J. 1D multiphysics modelling of PEM water electrolysis anodes with porous transport layers and the membrane. Chem. Eng. Sci., 2022, 253 117600

[196]

Lindquist GA, Gaitor JC, Thompson WL, et al. . Oxidative instability of ionomers in hydroxide-exchange-membrane water electrolyzers. Energy Environ. Sci., 2023, 16: 4373-4387

[197]

Volk EK, Kreider ME, Kwon S, et al. . Recent progress in understanding the catalyst layer in anion exchange membrane electrolyzers–durability, utilization, and integration. EES Catal., 2024, 2: 109-137

[198]

Liu JJ, Kang ZY, Li DG, et al. . Elucidating the role of hydroxide electrolyte on anion-exchange-membrane water electrolyzer performance. J. Electrochem. Soc., 2021, 168 054522

[199]

Ayers K, Danilovic N, Ouimet R, et al. . Perspectives on low-temperature electrolysis and potential for renewable hydrogen at scale. Annu. Rev. Chem. Biomol. Eng., 2019, 10: 219-239

[200]

Mulk WU, Aziz ARA, Ismael MA, et al. . Electrochemical hydrogen production through anion exchange membrane water electrolysis (AEMWE): recent progress and associated challenges in hydrogen production. Int. J. Hydrogen Energy, 2024, 94: 1174-1211

[201]

Yang HY, Driess M, Menezes PW. Self-supported electrocatalysts for practical water electrolysis. Adv. Energy Mater., 2021, 11 2102074

[202]

Fu SQ, Hu B, Ge JH, et al. . Application of ionized intrinsic microporous poly(phenyl-alkane)s as alkaline ionomers for anion exchange membrane water electrolyzers. Macromolecules, 2023, 56: 6037-6050

[203]

Huang JQ, Yu ZX, Tang JL, et al. . A review on anion exchange membranes for fuel cells: anion-exchange polyelectrolytes and synthesis strategies. Int. J. Hydrogen Energy, 2022, 47: 27800-27820

[204]

Cossar E, Murphy F, Walia J, et al. . Role of ionomers in anion exchange membrane water electrolysis: is aemion the answer for nickel-based anodes?. ACS Appl. Energy Mater., 2022, 5: 9938-9951

[205]

Ghorui UK, Sivaguru G, Teja UB, et al. . Anion-exchange membrane water electrolyzers for green hydrogen generation: advancement and challenges for industrial application. ACS Appl. Energy Mater., 2024, 7: 7649-7676

[206]

Wan L, Liu J, Xu ZA, et al. . Construction of integrated electrodes with transport highways for pure-water-fed anion exchange membrane water electrolysis. Small, 2022, 18 2200380

[207]

Ott S, Orfanidi A, Schmies H, et al. . Ionomer distribution control in porous carbon-supported catalyst layers for high-power and low Pt-loaded proton exchange membrane fuel cells. Nat. Mater., 2020, 19: 77-85

[208]

Matanovic I, Maurya S, Park EJ, et al. . Adsorption of polyaromatic backbone impacts the performance of anion exchange membrane fuel cells. Chem. Mater., 2019, 31: 4195-4204

[209]

Omasta TJ, Park AM, LaManna JM, et al. . Correction: Beyond catalysis and membranes: visualizing and solving the challenge of electrode water accumulation and flooding in AEMFCs. Energy Environ. Sci., 2018, 11: 995

[210]

Chen BY, Mardle P, Holdcroft S. Probing the effect of ionomer swelling on the stability of anion exchange membrane water electrolyzers. J. Power. Sources, 2022, 550 232134

[211]

Zhang JJ, Zhang KY, Liang X, et al. . Self-aggregating cationic-chains enable alkaline stable ion-conducting channels for anion-exchange membrane fuel cells. J. Mater. Chem. A, 2021, 9: 327-337

[212]

Liu XD, Wu DR, Liu X, et al. . Perfluorinated comb-shaped cationic polymer containing long-range ordered main chain for anion exchange membrane. Electrochim. Acta, 2020, 336 135757

[213]

Wang M, Park JH, Kabir S, et al. . Impact of catalyst ink dispersing methodology on fuel cell performance using in-situ X-ray scattering. ACS Appl. Energy Mater., 2019, 2: 6417-6427

[214]

Park J, Kang ZY, Bender G, et al. . Roll-to-roll production of catalyst coated membranes for low-temperature electrolyzers. J. Power. Sources, 2020, 479 228819

[215]

Volk EK, Clauser AL, Kreider ME, et al. . Role of the ionomer in supporting electrolyte-fed anion exchange membrane water electrolyzers. ACS Electrochem., 2025, 1: 239-248

[216]

Li DG, Park EJ, Zhu WL, et al. . Highly quaternized polystyrene ionomers for high performance anion exchange membrane water electrolysers. Nat. Energy, 2020, 5: 378-385

[217]

Chen MJ, Mandal M, Groenhout K, et al. . Self-adhesive ionomers for durable low-temperature anion exchange membrane electrolysis. J. Power. Sources, 2022, 536 231495

[218]

[219]

Hyun J, Doo G, Oh E, et al. . Anode reinforcement by polydopamine glue in anion exchange membrane water electrolysis. ACS Energy Lett., 2023, 8: 5240-5247

[220]

Faid AY, Barnett AO, Seland F, et al. . Ternary NiCoFe nanosheets for oxygen evolution in anion exchange membrane water electrolysis. Int. J. Hydrogen Energy, 2022, 47: 23483-23497

[221]

Adhikari S, Pagels MK, Jeon JY, et al. . Ionomers for electrochemical energy conversion & storage technologies. Polymer, 2020, 211 123080

[222]

Lim J, Klein JM, Lee SG, et al. . Addressing the challenge of electrochemical ionomer oxidation in future anion exchange membrane water electrolyzers. ACS Energy Lett., 2024, 9: 3074-3083

[223]

Matanovic I, Kim YS. Electrochemical phenyl oxidation: a limiting factor of oxygen evolution reaction in water electrolysis. Curr. Opin. Electrochem., 2023, 38 101218

[224]

Li DG, Matanovic I, Lee AS, et al. . Phenyl oxidation impacts the durability of alkaline membrane water electrolyzer. ACS Appl. Mater. Interfaces, 2019, 11: 9696-9701

[225]

Arslan G, Yazici B, Erbil M. The effect of pH, temperature and concentration on electrooxidation of phenol. J. Hazard. Mater., 2005, 124: 37-43

[226]

Hu C, Lee YJ, Sohn JY, et al. . ETFE-grafting ionomers for anion exchange membrane water electrolyzers with a current density of 11.2 A cm^–2. J. Power. Sources, 2024, 599 234228

[227]

Hassan NU, Mandal M, Zulevi B, et al. . Understanding and improving anode performance in an alkaline membrane electrolyzer using statistical design of experiments. Electrochim. Acta, 2022, 409 140001

[228]

Ferriday TB, Sampathkumar SN, Middleton PH, et al. . A review of membrane electrode assemblies for the anion exchange membrane water electrolyser: perspective on activity and stability. Int. J. Energy Res., 2024,

[229]

Park JE, Choi HJ, Kang SY, et al. . Effect of pore structures in nickel-based porous transport layers for high-performance and durable anion-exchange membrane water electrolysis. Int. J. Energy Res., 2022, 46: 16670-16678

[230]

Shoesmith, D.W., Noël, J.J.: Corrosion of titanium and its alloys. Shreir’s Corrosion. Elsevier, pp 2042–2052 (2010). https://doi.org/10.1016/b978-044452787-5.00097-4

[231]

Lee JK, Schuler T, Bender G, et al. . Interfacial engineering via laser ablation for high-performing PEM water electrolysis. Appl. Energy, 2023, 336 120853

[232]

Xu QC, Oener SZ, Lindquist G, et al. . Integrated reference electrodes in anion-exchange-membrane electrolyzers: Impact of stainless-steel gas-diffusion layers and internal mechanical pressure. ACS Energy Lett., 2021, 6: 305-312

[233]

Lettenmeier P, Kolb S, Sata N, et al. . Comprehensive investigation of novel pore-graded gas diffusion layers for high-performance and cost-effective proton exchange membrane electrolyzers. Energy Environ. Sci., 2017, 10: 2521-2533

[234]

Razmjooei F, Morawietz T, Taghizadeh E, et al. . Increasing the performance of an anion-exchange membrane electrolyzer operating in pure water with a nickel-based microporous layer. Joule, 2021, 5: 1776-1799

[235]

Huang BR, Wang XC, Li WZ, et al. . Accelerating gas escape in anion exchange membrane water electrolysis by gas diffusion layers with hierarchical grid gradients. Angew. Chem. Int. Ed., 2023, 62 e202304230

[236]

Iwata R, Zhang LN, Wilke KL, et al. . Bubble growth and departure modes on wettable/non-wettable porous foams in alkaline water splitting. Joule, 2021, 5: 887-900

[237]

Yuan S, Zhao CF, Cai XY, et al. . Bubble evolution and transport in PEM water electrolysis: mechanism, impact, and management. Prog. Energy Combust. Sci., 2023, 96 101075

[238]

Yang FC, Kim MJ, Brown M, et al. . Alkaline water electrolysis at 25 A cm⁻² with a microfibrous flow-through electrode. Adv. Energy Mater., 2020, 10 2001174

[239]

Xu QC, Zhang LY, Zhang JH, et al. . Anion exchange membrane water electrolyzer: electrode design, lab-scaled testing system and performance evaluation. EnergyChem, 2022, 4 100087

[240]

Grigoriev SA, Millet P, Volobuev SA, et al. . Optimization of porous current collectors for PEM water electrolysers. Int. J. Hydrog. Energy, 2009, 34: 4968-4973

[241]

Huang BR, Lei C, Sun XM, et al. . Improving mass transfer in anion exchange membrane water electrolysis by ordered gas diffusion layer. Int. J. Hydrog. Energy, 2023, 48: 35453-35462

[242]

Chen BY, Biancolli ALG, Radford CL, et al. . Stainless steel felt as a combined OER electrocatalyst/porous transport layer for investigating anion-exchange membranes in water electrolysis. ACS Energy Lett., 2023, 8: 2661-2667

[243]

Sampathkumar SN, Ferriday TB, Middleton PH, et al. . Activation of stainless steel 316L anode for anion exchange membrane water electrolysis. Electrochem. Commun., 2023, 146 107418

[244]

Lei J, Wang ZY, Zhang YZ, et al. . Understanding and resolving the heterogeneous degradation of anion exchange membrane water electrolysis for large-scale hydrogen production. Carbon Neutrality, 2024, 3 25

[245]

Nakagawa, T., Matsushima, H., Ueda, M., et al.: Corrosion behavior of SUS304L steel in high pH NaOH solution. Meet. Abstr. MA2020–01, 984 (2020). https://doi.org/10.1149/ma2020-0114984mtgabs

[246]

Rojas N, Sánchez-Molina M, Sevilla G, et al. . Coated stainless steels evaluation for bipolar plates in PEM water electrolysis conditions. Int. J. Hydrog. Energy, 2021, 46: 25929-25943

[247]

Aldakheel F, Kandekar C, Bensmann B, et al. . Electro-chemo-mechanical induced fracture modeling in proton exchange membrane water electrolysis for sustainable hydrogen production. Comput. Methods Appl. Mech. Eng., 2022, 400 115580

[248]

Pan YW, Wang HZ, Brandon NP. Gas diffusion layer degradation in proton exchange membrane fuel cells: mechanisms, characterization techniques and modelling approaches. J. Power. Sources, 2021, 513 230560

[249]

Qiu DK, Janßen H, Peng LF, et al. . Electrical resistance and microstructure of typical gas diffusion layers for proton exchange membrane fuel cell under compression. Appl. Energy, 2018, 231: 127-137

[250]

Yu L, Tian B, Huang WT, et al. . Advancements in ordered membrane electrode assembly (MEA) for water electrolysis. Curr. Opin. Electrochem., 2024, 48 101595

[251]

Yoon KY, Lee KB, Jeong J, et al. . Improved oxygen evolution reaction kinetics with titanium incorporated nickel ferrite for efficient anion exchange membrane electrolysis. ACS Catal., 2024, 14: 4453-4462

[252]

Lou KY, Xia L, Friedrich J, et al. . Tailoring high-performance catalyst architectures via ‘accessional ionomer coatings’ for anion exchange membrane water electrolysis. Int. J. Hydrog. Energy, 2024, 49: 591-603

[253]

Osmieri L, Yu HR, Hermann RP, et al. . Aerogel-derived nickel-iron oxide catalysts for oxygen evolution reaction in alkaline media. Appl. Catal. B Environ. Energy, 2024, 348 123843

[254]

Hassan NU, Motyka E, Kweder J, et al. . Effect of porous transport layer properties on the anode electrode in anion exchange membrane electrolyzers. J. Power. Sources, 2023, 555 232371

[255]

Ito H, Miyazaki N, Sugiyama S, et al. . Investigations on electrode configurations for anion exchange membrane electrolysis. J. Appl. Electrochem., 2018, 48: 305-316

[256]

Miller HA, Bouzek K, Hnat J, et al. . Green hydrogen from anion exchange membrane water electrolysis: a review of recent developments in critical materials and operating conditions. Sustain. Energy Fuels, 2020, 4: 2114-2133

[257]

Rossini M, Koyutürk B, Eriksson B, et al. . Rational design of membrane electrode assembly for anion exchange membrane water electrolysis systems. J. Power. Sources, 2024, 614 235062

[258]

Park JE, Bae HE, Karuppannan M, et al. . Effect of catalyst layer designs for high-performance and durable anion-exchange membrane water electrolysis. J. Ind. Eng. Chem., 2022, 109: 453-460

[259]

Mardle P, Chen BY, Holdcroft S. Opportunities of ionomer development for anion-exchange membrane water electrolysis: focus review. ACS Energy Lett., 2023, 8: 3330-3342

[260]

Guo WW, Kim J, Kim H, et al. . Direct electrodeposition of Ni-Co-S on carbon paper as an efficient cathode for anion exchange membrane water electrolysers. Int. J. Energy Res., 2021, 45: 1918-1931

[261]

Park JE, Sung YE, Choi C. Hierarchically porous, biaxially woven carbon nanotube sheet arrays for next-generation anion-exchange membrane water electrolyzers. J. Mater. Chem. A, 2022, 10: 20517-20524

[262]

Barati Darband G, Aliofkhazraei M, Hyun S, et al. . Pulse electrodeposition of a superhydrophilic and binder-free Ni–Fe–P nanostructure as highly active and durable electrocatalyst for both hydrogen and oxygen evolution reactions. ACS Appl. Mater. Interfaces, 2020, 12: 53719-53730

[263]

Han S, Ryu JH, Lee WB, et al. . Translating the optimized durability of co-based anode catalyst into sustainable anion exchange membrane water electrolysis. Small, 2024, 20 2311052

[264]

Ma Y, Wang JJ, Liu XH, et al. . Short-time potentiostatic assisted borate to induce the generation of ultrathin NiFe LDH active phase for industrial-level water oxidation. Chem. Eng. J., 2024, 490 151490

[265]

Qiu HH, Obata K, Tsuburaya K, et al. . Impact of gas bubble slug on high-frequency resistance and cell voltage in water electrolysis device. J. Power. Sources, 2024, 611 234765

[266]

Woo J, Han S, Yoon J. Mn-doped sequentially electrodeposited co-based oxygen evolution catalyst for efficient anion exchange membrane water electrolysis. ACS Appl. Mater. Interfaces, 2024,

[267]

Chueh CC, Yu SE, Wu HC, et al. . Enhanced oxygen evolution reaction performance of NiMoO₄/carbon paper electrocatalysts in anion exchange membrane water electrolysis by atmospheric-pressure plasma jet treatment. Langmuir, 2024, 40: 24675-24686

[268]

Klingenhof M, Selve S, Günther CM, et al. . All platinum-group-metal-free alkaline exchange membrane water electrolyzers using direct hydrothermal catalyst deposition on raney Ni substrate. ACS Appl. Energy Mater., 2024, 7: 6856-6861

[269]

Li ZH, Lin GX, Wang LQ, et al. . Seed-assisted formation of NiFe anode catalysts for anion exchange membrane water electrolysis at industrial-scale current density. Nat. Catal., 2024, 7: 944-952

[270]

Lin XN, Li X, Shi L, et al. . In situ electrochemical restructuring B-doped metal–organic frameworks as efficient OER electrocatalysts for stable anion exchange membrane water electrolysis. Small, 2024, 20 2308517

[271]

Na JC, Yu HM, Jia SY, et al. . Electrochemical reconstruction of non-noble metal-based heterostructure nanorod arrays electrodes for highly stable anion exchange membrane seawater electrolysis. J. Energy Chem., 2024, 91: 370-382

[272]

Kong TH, Thangavel P, Shin S, et al. . In-situ ionomer-free catalyst-coated membranes for anion exchange membrane water electrolyzers. ACS Energy Lett., 2023, 8: 4666-4673

[273]

Wan L, Liu J, Lin DC, et al. . 3D-ordered catalytic nanoarrays interlocked on anion exchange membranes for water electrolysis. Energy Environ. Sci., 2024, 17: 3396-3408

[274]

Wan L, Xu ZA, Xu Q, et al. . Overall design of novel 3D-ordered MEA with drastically enhanced mass transport for alkaline electrolyzers. Energy Environ. Sci., 2022, 15: 1882-1892

[275]

Wang J, Liang CW, Ma XY, et al. . Dynamically adaptive bubbling for upgrading oxygen evolution reaction using lamellar fern-like alloy aerogel self-standing electrodes. Adv. Mater., 2024, 36 2307925

[276]

Hassan NU, Zheng YW, Kohl PA, et al. . KOH vs deionized water operation in anion exchange membrane electrolyzers. J. Electrochem. Soc., 2022, 169 044526

[277]

Shaik S, Kundu J, Yuan YL, et al. . Recent progress and perspective in pure water-fed anion exchange membrane water electrolyzers. Adv. Energy Mater., 2024, 14 2401956

[278]

Lei C, Yang KC, Wang GZ, et al. . Impact of catalyst reconstruction on the durability of anion exchange membrane water electrolysis. ACS Sustainable Chem. Eng., 2022, 10: 16725-16733

[279]

Krivina RA, Lindquist GA, Beaudoin SR, et al. . Anode catalysts in anion-exchange-membrane electrolysis without supporting electrolyte: conductivity, dynamics, and ionomer degradation. Adv. Mater., 2022, 34 2203033

[280]

Motealleh B, Liu ZC, Masel RI, et al. . Next-generation anion exchange membrane water electrolyzers operating for commercially relevant lifetimes. Int. J. Hydrog. Energy, 2021, 46: 3379-3386

[281]

Leng YJ, Chen G, Mendoza AJ, et al. . Solid-state water electrolysis with an alkaline membrane. J. Am. Chem. Soc., 2012, 134: 9054-9057

[282]

Soni R, Miyanishi S, Kuroki H, et al. . Pure water solid alkaline water electrolyzer using fully aromatic and high-molecular-weight poly(fluorene-alt-tetrafluorophenylene)-trimethyl ammonium anion exchange membranes and ionomers. ACS Appl. Energy Mater., 2021, 4: 1053-1058

[283]

Wan L, Xu ZA, Xu Q, et al. . Key components and design strategy of the membrane electrode assembly for alkaline water electrolysis. Energy Environ. Sci., 2023, 16: 1384-1430

[284]

Li LG, Wang PT, Shao Q, et al. . Recent progress in advanced electrocatalyst design for acidic oxygen evolution reaction. Adv. Mater., 2021, 33 2004243

[285]

Lindquist GA, Oener SZ, Krivina R, et al. . Performance and durability of pure-water-fed anion exchange membrane electrolyzers using baseline materials and operation. ACS Appl. Mater. Interfaces, 2021, 13: 51917-51924

[286]

Wu X, Scott K. Cu_xCo_3–_xO₄ (0 ≤x< 1) nanoparticles for oxygen evolution in high performance alkaline exchange membrane water electrolysers. J. Mater. Chem., 2011, 21: 12344

Funding

Guangzhou Municipal Science and Technology Project(2024A03J0308)

Science Fund for Distinguished Young Scholars of Guangdong Province(2022B1515020020)

Basic and Applied Basic Research Foundation of Guangdong Province(2022B1515120079)

National Natural Science Foundation of China(22250710133)

International Science and Technology Cooperation Project in Huangpu District(2023GH07)

Guangdong Engineering Technology Research Center for Hydrogen Energy and Fuel Cells

RIGHTS & PERMISSIONS

Shanghai University and Periodicals Agency of Shanghai University

PDF

Accesses

Citation

Detail

Sections

Recommended

About the journal

Aims & scope

Description

Editorial board

Abstracting / indexing

Cover gallery

Contact us

Browse

Latest issue

All volumes and issues

Most accessed

Most cited

Authors & reviewers

Online submisson