2022
DOI: 10.1021/acs.chemrev.1c00854
|View full text |Cite
|
Sign up to set email alerts
|

Anion-Exchange Membrane Water Electrolyzers

Abstract: This Review provides an overview of the emerging concepts of catalysts, membranes, and membrane electrode assemblies (MEAs) for water electrolyzers with anion-exchange membranes (AEMs), also known as zero-gap alkaline water electrolyzers. Much of the recent progress is due to improvements in materials chemistry, MEA designs, and optimized operation conditions. Research on anion-exchange polymers (AEPs) has focused on the cationic head/backbone/side-chain structures and key properties such as ionic conductivity… Show more

Help me understand this report

Search citation statements

Order By: Relevance

Paper Sections

Select...
4
1

Citation Types

1
237
1
1

Year Published

2022
2022
2024
2024

Publication Types

Select...
9
1

Relationship

0
10

Authors

Journals

citations
Cited by 382 publications
(240 citation statements)
references
References 457 publications
1
237
1
1
Order By: Relevance
“…Hydrogen, a clean energy carrier, is considered as a potential substitute for fossil fuels. Among all the hydrogen production technologies, AEMWE has developed rapidly in recent years. As a water electrolysis technology, the advantage of AEMWE is its capability to use nonprecious metal electrocatalysts in both cathodes and anodes due to its alkaline environment, as well as a zero-gap cell structure to effectively reduce the ohmic polarization of the electrolyzer. , …”
Section: Introductionmentioning
confidence: 99%
“…Hydrogen, a clean energy carrier, is considered as a potential substitute for fossil fuels. Among all the hydrogen production technologies, AEMWE has developed rapidly in recent years. As a water electrolysis technology, the advantage of AEMWE is its capability to use nonprecious metal electrocatalysts in both cathodes and anodes due to its alkaline environment, as well as a zero-gap cell structure to effectively reduce the ohmic polarization of the electrolyzer. , …”
Section: Introductionmentioning
confidence: 99%
“…61−64 The O 2 solubility and diffusion limitations can primarily be addressed by the use of catalyst-loaded hydrophobic gas diffusion electrodes (GDEs) and flow cells to deliver a constant flow of O 2 gas directly to the catalyst surface at the three-phase boundary. Such benefits of the engineered electrochemical devices, which have been well studied for water-splitting electrolyzers 65 and CO 2 electroreduction devices, 66 are starting to be exploited for practical electrosynthesis of H 2 O 2 . 61−64 In a recent work, a GDE coated with a layer-templated CoSe 2 (sc-CoSe 2 ) catalyst was run in a flow cell (Figure 10a) and achieved a large H 2 O 2 partial current density up to 60 mA cm −2 (Figure 10b) for high-rate and selective H 2 O 2 production in recirculated 0.5 M H 2 SO 4 .…”
Section: Electrosynthesis Of H 2 Omentioning
confidence: 99%
“…[1,2] Nowadays, there are two commercially available water electrolysis systems: alkaline water electrolyzer (AWE) and proton exchange membrane water electrolyzer (PEM-WE). [3][4][5] However, AWE shows poor efficiency due to the high impedance of the electrolyte and diagram, while the large-scale application of PEM-WE is restricted by the high capital cost of noble metal-based catalysts and the device. To overcome these shortcomings, anion exchange membrane water electrolyzer (AEM-WE) has developed as a novel approach for large-scale hydrogen production owing to its compact design similar to PEM-WE and usage of non-noble hydrogen evolution reaction (HER) and oxygen evolving reaction (OER) catalysts, yet is still impeded by poor stability and low energy efficiency.…”
Section: Introductionmentioning
confidence: 99%