posted on 2024-08-02, 06:43authored byYanyan Li, Haoran Guo, Jiayang Zhao, Kanglei Pang, Rui Song
Surface reconstruction generates genuine active phases
under an
electrochemical oxygen evolution reaction (OER); however, most OER
catalysts exhibit slow self-reconstruction due to their relative stability
in electrochemistry. Therefore, it is highly essential to rationally
design precatalysts capable of rapidly generating more active OER
species. Herein, a novel reconfigurable Te-doped NiFe layered double
hydroxide (Te-NiFe LDH/NF) precatalyst is prepared, which exhibits
ultrafast and in-depth self-reconstruction, significantly enhancing
the activity for the OER step. By employing various in/ex situ techniques
and theoretical calculations, the distinctive structure of Te-NiFe
LDH/NF along with the alkaline electrolyte are identified as pivotal
factors for facilitating the phase transition. The presence of Te
cations can effectively reduce the energy barrier, thereby providing
the feasibility of continuous reconstruction, while the alkaline electrolyte
supplies a complement of OH– to form highly active
oxyhydroxides. Besides, Te is doped in situ into the NiFeOxHy lattice (Te-NiFeOxHy/NF), leading
to optimized binding energies of the OER intermediates and reduced
energy barriers for the rate-determining step (RDS), ultimately enhancing
the OER performance. As such, the self-restructured Te-NiFeOxHy/NF only required 208
and 310 mV to achieve 10 and 500 mA cm–2, respectively,
together with high current stability for 300 h. This study provides
a rational design strategy to develop highly efficient electrocatalysts
for the OER through surface reconstruction.