1. Revealing the effect of crystallinity and oxygen vacancies of Fe-Co phosphate on oxygen evolution for high-current water splitting.
- Author
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Liu, Xinqiang, Yin, Haoran, Zhang, Shifan, Huang, Menghan, Taylor Isimjan, Tayirjan, Yang, Xiulin, and Cai, Dandan
- Subjects
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OXYGEN evolution reactions , *PHASE transitions , *CRYSTALLINITY , *OXYGEN , *TRANSITION metals - Abstract
A diamond-like amorphous Fe-Co-PO x catalyst is created through a controllable amorphization engineering. It showcases wonderful OER activity, reaching a potential of 270 mV at 10 mA cm−2, and can operate as an anode stably at 200 mA cm−2 for 300 h with little degradation in overall water splitting. Studies observe that the unique amorphous structure, abundant oxygen vacancies, and the synergistic effect of Fe and Co species are the keys to gain excellent water splitting performance. [Display omitted] • An amorphous FeCo-PO x is constructed by hydrothermal and phosphating treatments. • The catalyst owns a diamond-like morphology and abundant oxygen vacancies. • The catalyst exhibits excellent OER and overall water splitting activity and stability. • The synergy of rich oxygen vacancy and amorphous structure are the key to improve performance. Strategically tuning the composition and structure of transition metal phosphates (TMPs) holds immense promise in the development of efficient oxygen evolution reaction (OER) electrocatalysts. However, the effect of crystalline phase transformation for TMPs on the catalytic OER activity remains relatively uncharted. In this study, we have deftly orchestrated the reaction process of anion-etched precursor to induce the amorphization process of FeCo-PO x from crystalline to amorphous states. The as-obtained amorphous FeCo-PO x (A-FeCo-PO x) exhibited an optimized OER performance with a low overpotential of 270 mV at a current density of 10 mA cm−2, which could be attributed to the flexibility of its amorphous structure and the synergistic effect of oxygen vacancies. Moreover, when incorporated into an overall water splitting (OWS) device configured as A-FeCo-POx(+)||Pt/C(–), it displayed long-term solid stability, sustaining operation for 300 h at a current density of 200 mA cm−2. This work not only provides valuable insights into understanding the transformation from crystalline to amorphous states, but also establishes the groundwork for the practical utilization of amorphous nanomaterials in the field of water splitting. [ABSTRACT FROM AUTHOR]
- Published
- 2024
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