Recent Progress and Perspective in Pure Water‐Fed Anion Exchange Membrane Water Electrolyzers

Shaik, Shajahan; Kundu, Joyjit; Yuan, Yuliang; Chung, Wonsuk; Han, Donggu; Lee, Ung; Huang, Hongwen; Choi, Sang‐Il

doi:10.1002/aenm.202401956

Advanced Energy Materials

2024

DOI: 10.1002/aenm.202401956

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Recent Progress and Perspective in Pure Water‐Fed Anion Exchange Membrane Water Electrolyzers

Shajahan Shaik,

Joyjit Kundu,

Yuliang Yuan

et al.

Abstract: Although anion exchange membrane water electrolyzer (AEMWE) is an emerging device in the green hydrogen production industry, the use of alkaline electrolyte tackles the practicality due to the issues of lowering system efficiency and environmental impacts. State‐of‐the‐art technology using pure water as an electrolyte is advancing to overcome the current challenges of AEMWE. In particular, the development of this technology requires a comprehensive evaluation of techno‐economic aspects, aiming to balance innov… Show more

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Cited by 4 publications

References 99 publications

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Epitaxial Growth of PdH@Ru Hollow Nanobamboos for Efficient Hydrogen Evolution in Anion Exchange Membrane Electrolyzer

Jiang,

Wang,

Ding

et al. 2024

Adv Funct Materials

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In‐depth comprehension and improvement of the sluggish hydrogen evolution kinetics in alkaline media is highly important to enhance the activity and durability of anion exchange membrane water electrolysis (AEMWE) for green hydrogen production. Herein, a hydrogen atom‐terminated core–shell PdH@Ru nanobamboos (NBs) is developed by the synergetic strategy of epitaxial growth and in situ DMF hydrogenation. The synthesized PdH@Ru NBs demonstrate exceptional activity for hydrogen evolution reaction (HER) in alkaline media, requiring only a 14 mV overpotential at the 10 mA cm−2, surpassing those of commercial Pt/C (35 mV) and H‐free Pd@Ru NBs (37 mV). Furthermore, an AEMWE device using PdH@Ru NBs as the cathode also achieves the current density of 1000 mA cm−2 at ≈1.80 V in 1.0 m KOH at 60 °C, with continuous operation for 50 h. The operando spectroscopic analysis and density functional theory calculations suggest that hydrogen insertion into the Pd@Ru NBs induces tensile strain on the Ru surface layer, altering the Pd/Ru electronic structure and weakening H adsorption, thereby enhancing the HER efficiency. The bamboo‐like hollow structure features numerous active sites, which contribute to the optimization of electron/mass diffusion in the alkaline electrolyte. This work provides a potential high‐efficiency cathodic electrocatalyst for industrial hydrogen production.

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Epitaxial Growth of PdH@Ru Hollow Nanobamboos for Efficient Hydrogen Evolution in Anion Exchange Membrane Electrolyzer

Jiang,

Wang,

Ding

et al. 2024

Adv Funct Materials

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Self‐Supported Metallic Alkaline Hydrogen Evolution Electrocatalysts Tolerant for Ampere‐Level Current Densities

Xiong,

Zhuang,

Cheng

et al. 2024

Advanced Energy Materials

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Electrocatalytic water splitting is an attractive approach for large‐scale hydrogen generation, critical for global carbon neutrality. However, the prevalent commercialized alkaline water electrolysis is generally conducted at low current densities due to sluggish kinetics and high overpotential, severely hampering high‐efficiency hydrogen production. Exploration of hydrogen evolution reaction (HER) electrocatalysts that can reliably operate at ampere‐level current densities under low overpotentials is thus a primary challenge. In contrast to extensive studies using powdery electrocatalysts, the self‐supported metallic catalytic cathode has become a burgeoning direction toward ampere‐level current densities, owing to their integrated design with intensive interfacial binding, high conductivity and mechanical stability with industrial tolerance/adaption. Recent years have witnessed tremendous research advances in designing self‐supported metallic electrocatalysts. Therefore, this flourishing area is specially summarized. Beginning with the introduction to the theory and mechanism of alkaline HER, the engineering strategies on self‐supported metallic electrodes are systematically summarized, including metal and alloy construction, heterostructure engineering, doping manipulation, and surface design. Meanwhile, particular emphasis is focused on the relationship between structure, activity, and stability under ampere‐level HER. Finally, the existing challenges, requirements of industrial‐scale application, and future direction for designing electrocatalysts are summarized, aiming to provide a better solution for industrial alkaline water electrolysis.

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Novel Atmospherically Plasma Sprayed Micro Porous Layer for Anion Exchange Membrane Water Electrolysis Operating With Supporting Electrolyte

Wilke,

Rivera,

Morawietz

et al. 2024

Electrochemical Science Adv

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Anion exchange membrane water electrolysis (AEMWE) is one of the most promising candidates for green hydrogen production needed for the de‐fossilization of the global economy. As AEMWE can operate at high efficiency without expensive Platinum Group Metal (PGM) catalysts or titanium cell components, required in state‐of‐the‐art proton exchange membrane electrolysis (PEMWE), AEMWE has the potential to become a cheaper alternative in large‐scale production of green hydrogen. In AEMWE, the porous transport layer and/or micro porous layer (PTL/MPL) has to balance several important tasks. It is responsible for managing transport of electrolyte and/or liquid water to the catalyst layers (CLs), transport of evolving gas bubbles away from the CLs and establishing thermal and electrical connection between the CLs and bipolar plates (BPPs). Furthermore, especially in case the CL is directly deposited onto the MPL, forming a catalyst‐coated substrate (CCS), the MPL surface properties significantly impact CL stability. Thus, the MPL is one of the key performance‐defining components in AEMWE. In this study, we employed the flexible and easily upscaled technique of atmospheric plasma spraying (APS) to deposit spherical nickel coated graphite directly on a low‐cost mesh PTL. Followed by oxidative carbon removal, a nickel‐based MPL with superior structural parameters compared to a state‐of‐art nickel felt MPL was produced. Due to a higher activity of the nickel APS‐MPL itself, as well as improved catalyst utilization, a reduction in cell voltage of 63 mV at 2 A cm−2 was achieved in an AEMWE operating with 1 M KOH electrolyte. This improvement was enabled by the high internal surface area and the unique pore structure of the APS‐MPL with a broad pore size distribution as well as the finely structured surface providing a large contacting area to the CLs.

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Recent Progress and Perspective in Pure Water‐Fed Anion Exchange Membrane Water Electrolyzers

Cited by 4 publications

References 99 publications

Epitaxial Growth of PdH@Ru Hollow Nanobamboos for Efficient Hydrogen Evolution in Anion Exchange Membrane Electrolyzer

Epitaxial Growth of PdH@Ru Hollow Nanobamboos for Efficient Hydrogen Evolution in Anion Exchange Membrane Electrolyzer

Self‐Supported Metallic Alkaline Hydrogen Evolution Electrocatalysts Tolerant for Ampere‐Level Current Densities

Novel Atmospherically Plasma Sprayed Micro Porous Layer for Anion Exchange Membrane Water Electrolysis Operating With Supporting Electrolyte

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