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Role of Physicochemical Features toward Bifunctional Redox Activity of Transition-Metal Molybdates
In recent years, the search for non-noble metal-based bi-functional electrode materials with excellent activity and stability for overall water splitting has led the energy field research toward transition-metal (TM)-based materials that are abundant and comparatively stable over a wide range of pH....
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| Published in: | ACS sustainable chemistry & engineering 2023-09, Vol.11 (35), p.13013-13023 |
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| Main Authors: | , , , , |
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| container_issue | 35 |
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| container_title | ACS sustainable chemistry & engineering |
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| creator | Jana, Jayasmita Sharma, Tata Sanjay Kanna Chung, Jin Suk Choi, Won Mook Hur, Seung Hyun |
| description | In recent years, the search for non-noble metal-based bi-functional electrode materials with excellent activity and stability for overall water splitting has led the energy field research toward transition-metal (TM)-based materials that are abundant and comparatively stable over a wide range of pH. Herein, a series of late first-row TM molybdates (TMMo, TM = Co, Ni, Cu, and Zn) were studied for alkaline water splitting, where the materials were synthesized through a surfactant confinement reaction via the hydrothermal process. The microscopic analyses showed varied morphology like, fusiform, forest, disks, and rugby ball with multivalency and monoclinic/triclinic crystal structures of the TMMo materials. Among the molybdates, CoMo, with a larger number of active sites with an inequivalent atomic position in the cluster and upshifted d/p bands showed the best activity as both cathode and anode materials with the overpotentials of 280 and 408 mV, respectively, to obtain a current density of 100 mA cm–2. CoMo exhibited faster reaction kinetics over other molybdates as it had lower charge-transfer resistance with significant stability. Furthermore, a two-electrode system with CoMo as the cathode and anode provided a lower cell voltage of 1.86 V at 100 mA cm–2 current density over commercial electrode materials, indicating CoMo can be an excellent commercial alternative electrocatalyst for overall water splitting. |
| doi_str_mv | 10.1021/acssuschemeng.3c02780 |
| format | article |
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Herein, a series of late first-row TM molybdates (TMMo, TM = Co, Ni, Cu, and Zn) were studied for alkaline water splitting, where the materials were synthesized through a surfactant confinement reaction via the hydrothermal process. The microscopic analyses showed varied morphology like, fusiform, forest, disks, and rugby ball with multivalency and monoclinic/triclinic crystal structures of the TMMo materials. Among the molybdates, CoMo, with a larger number of active sites with an inequivalent atomic position in the cluster and upshifted d/p bands showed the best activity as both cathode and anode materials with the overpotentials of 280 and 408 mV, respectively, to obtain a current density of 100 mA cm–2. CoMo exhibited faster reaction kinetics over other molybdates as it had lower charge-transfer resistance with significant stability. 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Eng</addtitle><date>2023-09-04</date><risdate>2023</risdate><volume>11</volume><issue>35</issue><spage>13013</spage><epage>13023</epage><pages>13013-13023</pages><issn>2168-0485</issn><eissn>2168-0485</eissn><abstract>In recent years, the search for non-noble metal-based bi-functional electrode materials with excellent activity and stability for overall water splitting has led the energy field research toward transition-metal (TM)-based materials that are abundant and comparatively stable over a wide range of pH. Herein, a series of late first-row TM molybdates (TMMo, TM = Co, Ni, Cu, and Zn) were studied for alkaline water splitting, where the materials were synthesized through a surfactant confinement reaction via the hydrothermal process. The microscopic analyses showed varied morphology like, fusiform, forest, disks, and rugby ball with multivalency and monoclinic/triclinic crystal structures of the TMMo materials. 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| source | American Chemical Society:Jisc Collections:American Chemical Society Read & Publish Agreement 2022-2024 (Reading list) |
| title | Role of Physicochemical Features toward Bifunctional Redox Activity of Transition-Metal Molybdates |
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