In situ oxidation transformation of trimetallic selenide to amorphous FeCo-oxyhydroxide by self-sacrificing MoSe₂ for efficient water oxidation
Transition metal chalcogenides have emerged as unique electrocatalysts for the oxygen evolution reaction (OER) during which they usually undergo an oxidation transformation into active oxides/(oxy)hydroxides. However, the transformation is so rapid that a high exposure of as-transformed (oxy)hydroxi...
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sg-ntu-dr.10356-1549132022-01-14T05:49:09Z In situ oxidation transformation of trimetallic selenide to amorphous FeCo-oxyhydroxide by self-sacrificing MoSe₂ for efficient water oxidation Tang, Yu-Jia Wang, Yu Zhou, Kun School of Mechanical and Aerospace Engineering Nanyang Environment and Water Research Institute Engineering::Environmental engineering Evolution Oxygen Transition metal chalcogenides have emerged as unique electrocatalysts for the oxygen evolution reaction (OER) during which they usually undergo an oxidation transformation into active oxides/(oxy)hydroxides. However, the transformation is so rapid that a high exposure of as-transformed (oxy)hydroxides cannot be achieved, thereby hindering the OER efficiency of the electrocatalyst. Herein, we report a simple self-sacrificing strategy to increase this exposure. A trimetallic selenide heterostructure (FeCoMo-Se) consisting of FeSe₂, CoSe₂ and MoSe₂ is first one-step synthesized on a carbon cloth substrate. The heterostructure possesses a thin nanosheet morphology due to the support of MoSe₂ nanosheets as a structural template. Under OER conditions, FeSe₂ and CoSe₂ are then in situ converted to FeCo-oxyhydroxide while retaining the nanosheet morphology of the heterostructure. Interestingly, MoSe₂ is self-sacrificially dissolved and hence leaves considerable space to increase the exposure of FeCo-oxyhydroxide to the electrolyte. Such an advantageous nanostructure endows the FeCoMo-Se-transformed electrocatalyst with excellent OER performance in an alkaline medium, which is much higher than the non-MoSe₂-containing selenide FeCo-Se. Density functional calculations demonstrate the favorable intermediate bindings in FeCo-oxyhydroxide. This novel self-sacrificing strategy opens up new avenues in the development of high-performance OER electrocatalysts with respect to their in situ oxidation transformation. Nanyang Technological University The authors acknowledge the financial support from the Nanyang Environment and Water Research Institute (Core Fund), Nanyang Technological University, Singapore. 2022-01-14T05:49:09Z 2022-01-14T05:49:09Z 2020 Journal Article Tang, Y., Wang, Y. & Zhou, K. (2020). In situ oxidation transformation of trimetallic selenide to amorphous FeCo-oxyhydroxide by self-sacrificing MoSe₂ for efficient water oxidation. Journal of Materials Chemistry A, 8(16), 7925-7934. https://dx.doi.org/10.1039/C9TA14133B 2050-7488 https://hdl.handle.net/10356/154913 10.1039/C9TA14133B 16 8 7925 7934 en Journal of Materials Chemistry A © The Royal Society of Chemistry 2020. All rights reserved. |
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Engineering::Environmental engineering Evolution Oxygen Tang, Yu-Jia Wang, Yu Zhou, Kun In situ oxidation transformation of trimetallic selenide to amorphous FeCo-oxyhydroxide by self-sacrificing MoSe₂ for efficient water oxidation |
| description |
Transition metal chalcogenides have emerged as unique electrocatalysts for the oxygen evolution reaction (OER) during which they usually undergo an oxidation transformation into active oxides/(oxy)hydroxides. However, the transformation is so rapid that a high exposure of as-transformed (oxy)hydroxides cannot be achieved, thereby hindering the OER efficiency of the electrocatalyst. Herein, we report a simple self-sacrificing strategy to increase this exposure. A trimetallic selenide heterostructure (FeCoMo-Se) consisting of FeSe₂, CoSe₂ and MoSe₂ is first one-step synthesized on a carbon cloth substrate. The heterostructure possesses a thin nanosheet morphology due to the support of MoSe₂ nanosheets as a structural template. Under OER conditions, FeSe₂ and CoSe₂ are then in situ converted to FeCo-oxyhydroxide while retaining the nanosheet morphology of the heterostructure. Interestingly, MoSe₂ is self-sacrificially dissolved and hence leaves considerable space to increase the exposure of FeCo-oxyhydroxide to the electrolyte. Such an advantageous nanostructure endows the FeCoMo-Se-transformed electrocatalyst with excellent OER performance in an alkaline medium, which is much higher than the non-MoSe₂-containing selenide FeCo-Se. Density functional calculations demonstrate the favorable intermediate bindings in FeCo-oxyhydroxide. This novel self-sacrificing strategy opens up new avenues in the development of high-performance OER electrocatalysts with respect to their in situ oxidation transformation. |
| author2 |
School of Mechanical and Aerospace Engineering |
| author_facet |
School of Mechanical and Aerospace Engineering Tang, Yu-Jia Wang, Yu Zhou, Kun |
| format |
Article |
| author |
Tang, Yu-Jia Wang, Yu Zhou, Kun |
| author_sort |
Tang, Yu-Jia |
| title |
In situ oxidation transformation of trimetallic selenide to amorphous FeCo-oxyhydroxide by self-sacrificing MoSe₂ for efficient water oxidation |
| title_short |
In situ oxidation transformation of trimetallic selenide to amorphous FeCo-oxyhydroxide by self-sacrificing MoSe₂ for efficient water oxidation |
| title_full |
In situ oxidation transformation of trimetallic selenide to amorphous FeCo-oxyhydroxide by self-sacrificing MoSe₂ for efficient water oxidation |
| title_fullStr |
In situ oxidation transformation of trimetallic selenide to amorphous FeCo-oxyhydroxide by self-sacrificing MoSe₂ for efficient water oxidation |
| title_full_unstemmed |
In situ oxidation transformation of trimetallic selenide to amorphous FeCo-oxyhydroxide by self-sacrificing MoSe₂ for efficient water oxidation |
| title_sort |
in situ oxidation transformation of trimetallic selenide to amorphous feco-oxyhydroxide by self-sacrificing mose₂ for efficient water oxidation |
| publishDate |
2022 |
| url |
https://hdl.handle.net/10356/154913 |
| _version_ |
1722355335856914432 |