Carbon Energy (Sep 2024)

Enabling built‐in electric fields on rhenium‐vacancy‐rich heterojunction interfaces of transition‐metal dichalcogenides for pH‐universal efficient hydrogen and electric energy generation

  • Benzhi Wang,
  • Lixia Wang,
  • Ji Hoon Lee,
  • Tayirjan Taylor Isimjan,
  • Hyung Mo Jeong,
  • Xiulin Yang

DOI
https://doi.org/10.1002/cey2.526
Journal volume & issue
Vol. 6, no. 9
pp. n/a – n/a

Abstract

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Abstract Most advanced hydrogen evolution reaction (HER) catalysts show high activity under alkaline conditions. However, the performance deteriorates at a natural and acidic pH, which is often problematic in practical applications. Herein, a rhenium (Re) sulfide–transition‐metal dichalcogenide heterojunction catalyst with Re‐rich vacancies (NiS2‐ReS2‐V) has been constructed. The optimized catalyst shows extraordinary electrocatalytic HER performance over a wide range of pH, with ultralow overpotentials of 42, 85, and 122 mV under alkaline, acidic, and neutral conditions, respectively. Moreover, the two‐electrode system with NiS2‐ReS2‐V1 as the cathode provides a voltage of 1.73 V at 500 mA cm−2, superior to industrial systems. Besides, the open‐circuit voltage of a single Zn–H2O cell with NiS2‐ReS2‐V1 as the cathode can reach an impressive 90.9% of the theoretical value, with a maximum power density of up to 31.6 mW cm−2. Moreover, it shows remarkable stability, with sustained discharge for approximately 120 h at 10 mA cm−2, significantly outperforming commercial Pt/C catalysts under the same conditions in all aspects. A series of systematic characterizations and theoretical calculations demonstrate that Re vacancies on the heterojunction interface would generate a stronger built‐in electric field, which profoundly affects surface charge distribution and subsequently enhances HER performance.

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