Structures and properties of polymers in ion exchange membranes for hydrogen generation by water electrolysis

Gohil, Jaydevsinh M.; Dutta, Kingshuk

doi:10.1002/pat.5482

Cited by 12 publications

(9 citation statements)

References 107 publications

(180 reference statements)

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“…In addition, PF is easily obtained as the sufficiently high‐molecular weight with narrow polydispersity by the Suzuki‐Miyaura coupling polymerization. As the Suzuki‐Miyaura cross‐coupling of organodiboronic acid and organodihalides gives alternating copolymers, the IEC of the AEM can be selected by changing the combination of monomers 35 . The alkyl spacer between the polymer main chain and ion exchange groups is another crucial molecular design point.…”

Section: Resultsmentioning

confidence: 99%

“…Therefore, aromatic polymers with no heteroatom bonds in the polymer main chain are expected to show high chemical stability. For the study of polymer electrolyte fuel cells using AEMs, polyphenylene‐type and polyfluorene‐type AEMs have been reported as the desired main chains with high‐chemical stabilities 21,33–37 . Bae et al reported that AEMs with a terphenyl backbone with high‐alkaline stability maintain ion exchange capacity (IEC) even after immersion in an basic aqueous solution (1 M NaOH) at 95°C for 60 days 38 .…”

Section: Introductionmentioning

confidence: 99%

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Development of highly alkaline stable anion conductive polymers with fluorene backbone for water electrolysis

Nara

Tanaka

Kuroda

et al. 2022

Polymers for Advanced Techs

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Anion exchange membrane water electrolysis (AEMWE) is currently paying attention as a new hydrogen (H2) production method since it can operate at high current densities using inexpensive nonnoble metal catalysts. However, the significant problems of AEMs, including their insufficient anion conductivity and alkaline stability, prevent the practical usage of AEMWE. We show a novel anion conductive polymer, alkyl trimethylammonium‐substituted polyfluorene (TMA‐PF), bearing no heteroatom bonds in the main chain. The TMA‐PF membrane possesses higher anion conductivity than conventional AEMs due to the increased flexibility and mobility of the alkylammonium side chains of TMA‐PF. The TMA‐PF membrane shows high‐alkaline stability and maintains the initial ion conductivity after immersion in an aqueous NaOH solution (8 mol L−1) at 80°C for 48 h. In the water electrolysis evaluation, the cell using the TMA‐PF membrane exhibits a higher current density (400 mA cm−2 at 2.03 V) than the cell using the conventional AEM at the same potential, indicating that the novel AEM has a high potential to generate H2 effectively. Green hydrogen produced by AEMWE using renewable energy will be an environmentally benign energy source without CO2 emissions.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Development of highly alkaline stable anion conductive polymers with fluorene backbone for water electrolysis

Nara

Tanaka

Kuroda

et al. 2022

Polymers for Advanced Techs

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“…[1,2] Hydrogen, as a promising energy carrier, plays a significant role in the carbon-neutrality world because of its various advantages: sustainability, nontoxicity, and high energy contents. [3,4] The use of hydrogen mitigates the environmental impacts that occur with carbon-based fuels. However, unlike fossil fuels, hydrogen as a form of fuel is not available to use in nature.…”

Section: Introductionmentioning

confidence: 99%

Anion exchange membrane water electrolysis for sustainable large‐scale hydrogen production

Lee

Kim

Kwon

et al. 2022

Carbon Neutralization

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The development of sustainable energy technology has received considerable attention to meet the increasing energy demands and realize carbon neutrality. Hydrogen is a promising alternative energy source to replace fossil fuels and mitigate environmental issues. However, most hydrogen is produced by reforming fossil fuels, called gray hydrogen, and the production of gray hydrogen emits a large amount of carbon dioxide. As a sustainable approach, water electrolysis technology has been developed to produce high‐purity hydrogen, called green hydrogen. Among various technologies, water electrolysis equipped with an anion exchange membrane has been regarded as an attractive pathway for large‐scale H2 production at a low cost. The status of anion exchange membrane water electrolyzers is approaching toward megawatt‐scale H2 production by companies, which has the potential to become competitive technology for existing water electrolyzers (alkaline electrolyzer, proton exchange membrane electrolyser). This review article represents recent advances in the development of major components (membrane, catalyst, membrane electrode assembly) of anion exchange water electrolyzers. By recognizing the current water electrolysis performance and solving the remaining challenges, anion exchange membrane electrolysis can be a leading technology for green hydrogen production.

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“…[10][11][12][13][14][15][16][17] The recent development of AEM and anion-exchange ionomers for AEM-WE or AEM fuel cell application was reviewed in Refs. [18][19][20][21][22]. Particularly, AEMs developed for AEM-WE application were summarized in Refs.…”

mentioning

confidence: 99%

“…[20] In Ref. [21], a comprehensive Review related to the structures and properties of polymers in anion and cation exchange membranes for water electrolysis application is presented. Advances in AEMs for fuel cells and electrolyzers application were also presented by Mandal.…”

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confidence: 99%

What is Next in Anion‐Exchange Membrane Water Electrolyzers? Bottlenecks, Benefits, and Future

et al. 2022

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As highlighted by the recent roadmaps from the European Union and the United States, water electrolysis is the most valuable high‐intensity technology for producing green hydrogen. Currently, two commercial low‐temperature water electrolyzer technologies exist: alkaline water electrolyzer (A‐WE) and proton‐exchange membrane water electrolyzer (PEM‐WE). However, both have major drawbacks. A‐WE shows low productivity and efficiency, while PEM‐WE uses a significant amount of critical raw materials. Lately, the use of anion‐exchange membrane water electrolyzers (AEM‐WE) has been proposed to overcome the limitations of the current commercial systems. AEM‐WE could become the cornerstone to achieve an intense, safe, and resilient green hydrogen production to fulfill the hydrogen targets to achieve the 2050 decarbonization goals. Here, the status of AEM‐WE development is discussed, with a focus on the most critical aspects for research and highlighting the potential routes for overcoming the remaining issues. The Review closes with the future perspective on the AEM‐WE research indicating the targets to be achieved.

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Structures and properties of polymers in ion exchange membranes for hydrogen generation by water electrolysis

Cited by 12 publications

References 107 publications

Development of highly alkaline stable anion conductive polymers with fluorene backbone for water electrolysis

Development of highly alkaline stable anion conductive polymers with fluorene backbone for water electrolysis

Anion exchange membrane water electrolysis for sustainable large‐scale hydrogen production

What is Next in Anion‐Exchange Membrane Water Electrolyzers? Bottlenecks, Benefits, and Future

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