Crucial Role of Self‐Exsolved Heterostructured Cermet Nanoparticles in Highly Active Spinel Electrodes for CO<sub>2</sub>/H<sub>2</sub>O Co‐Electrolysis

Wu, Kuan‐Ting; Matsuda, Junko; Staykov, Aleksandar; Ishihara, Tatsumi

doi:10.1002/aenm.202301042

Cited by 3 publications

(1 citation statement)

References 92 publications

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“…In addition, Ni–Co alloy also exhibits superior redox tolerance due to the formation of a dense oxide film, which prevents Ni oxidation . Cu is a highly active alternative to Ni, particularly due to its excellent resistance to carbon deposition and it contributes to the reduction of CO 2 in SOEC. , However, its low melting point restricts its widespread use in high-temperature applications. While alloys can offer superior stability compared with nickel, current advancements in binary alloys are somewhat limited.…”

Section: Introductionmentioning

confidence: 99%

Toward High CO Selectivity and Oxidation Resistance Solid Oxide Electrolysis Cell with High-Entropy Alloy

Tong,

Ni,

Zhou

et al. 2024

ACS Catal.

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Ni-based cermet materials still persist as pronounced challenges for electrocatalysts in solid oxide electrolysis cells (SOECs), due to their insufficient CO2 catalytic efficiency and inferior resistance to oxidation. In this paper, a (Fe,Co,Ni,Cu,Mo) quinary high-entropy alloy is explored as an alternative cathode material, offering enhanced performance in the co-electrolysis of H2O and CO2 for renewable syngas production. In comparison to traditional nickel-based cathodes, an assembled SOEC employing the as-designed quinary high-entropy alloy exhibits a remarkable increase in CO2 conversion capacity and significantly enhanced oxidation resistance. In addition, the electrolysis current density increases by 18%, and a stability test for more than 110 h reveals no degradation. Moreover, the stability can be maintained for up to 40 h even without any protective gas. Morphological and spectroscopic analyses, coupled with density functional theory (DFT) calculations, elucidate that the high-entropy effect facilitates surface electron redistribution, which in turn contributes to the measurable activity by reducing the energy barrier of CO2 activation. Notably, the superior resistance to oxidation primarily originates from the in situ-formed spinel phase under oxidation conditions. This study demonstrates the satisfying performance of high-entropy alloys as cathode materials in SOEC, validating their high application potential in this field.

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Section: Introductionmentioning

confidence: 99%

Toward High CO Selectivity and Oxidation Resistance Solid Oxide Electrolysis Cell with High-Entropy Alloy

Tong,

Ni,

Zhou

et al. 2024

ACS Catal.

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Toward Advanced Fuel Electrodes for High‐Performance Proton‐Conducting Ceramic Cells

Jiang,

Zheng,

Sun

2024

Advanced Energy Materials

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Proton‐conducting ceramic cells (PCCs), which include proton‐conducting ceramic fuel cells (PCFCs) and proton‐conducting ceramic electrolysis cells (PCECs), have attracted significant attention as high‐efficiency and eco‐friendly technologies for energy conversion. As compared with the impressive progress made in air electrode and electrolyte materials, fuel electrodes have received much less attention due to the faster reaction kinetics and lower polarization. Nevertheless, the design and optimization of fuel electrodes is also critical toward further electrochemical performance improvement, especially when the fuel is extended from hydrogen to ammonia and hydrocarbons for PCFCs. Herein, the recent research progress on the design strategies for fuel electrodes of PCCs is overviewed, including impregnation strategy, exsolution strategy, addition of catalytic layers, and optimization of electrode structure. Finally, perspectives on the challenges facing the development of advanced PCCs fuel electrodes are presented.

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In situ TEM studies on hydrogen-related issues: hydrogen storage, hydrogen embrittlement, fuel cells and electrolysis

Matsuda

2023

Microscopy

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Hydrogen is attracting attention as an energy carrier for realizing a low-carbon society, because it can directly convert the energy obtained from chemical reactions into electrical energy without carbon dioxide emissions. This paper presents in situ transmission electron microscopic (TEM) observations related to hydrogen storage in metal and metal hydrides, hydrogen embrittlement of metallic materials used for storing and transporting hydrogen in containers and pipes, and fuel cells and water electrolysis using metal catalysts and oxides as electrode materials. All of these processes are important for practical applications of hydrogen. Numerous in situ TEM studies have revealed the microscopic structural changes when hydrogen reacts with the materials, when hydrogen is solidly dissolved in the materials, and during the operation of the material. This review is expected to facilitate further development of TEM operando observations of hydrogen-related materials.

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Crucial Role of Self‐Exsolved Heterostructured Cermet Nanoparticles in Highly Active Spinel Electrodes for CO₂/H₂O Co‐Electrolysis

Cited by 3 publications

References 92 publications

Toward High CO Selectivity and Oxidation Resistance Solid Oxide Electrolysis Cell with High-Entropy Alloy

Toward High CO Selectivity and Oxidation Resistance Solid Oxide Electrolysis Cell with High-Entropy Alloy

Toward Advanced Fuel Electrodes for High‐Performance Proton‐Conducting Ceramic Cells

In situ TEM studies on hydrogen-related issues: hydrogen storage, hydrogen embrittlement, fuel cells and electrolysis

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Crucial Role of Self‐Exsolved Heterostructured Cermet Nanoparticles in Highly Active Spinel Electrodes for CO2/H2O Co‐Electrolysis

Cited by 3 publications

References 92 publications

Toward High CO Selectivity and Oxidation Resistance Solid Oxide Electrolysis Cell with High-Entropy Alloy

Toward High CO Selectivity and Oxidation Resistance Solid Oxide Electrolysis Cell with High-Entropy Alloy

Toward Advanced Fuel Electrodes for High‐Performance Proton‐Conducting Ceramic Cells

In situ TEM studies on hydrogen-related issues: hydrogen storage, hydrogen embrittlement, fuel cells and electrolysis

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Crucial Role of Self‐Exsolved Heterostructured Cermet Nanoparticles in Highly Active Spinel Electrodes for CO₂/H₂O Co‐Electrolysis