Nature Communications (Apr 2023)

Oxynitrides enabled photoelectrochemical water splitting with over 3,000 hrs stable operation in practical two-electrode configuration

  • Yixin Xiao,
  • Xianghua Kong,
  • Srinivas Vanka,
  • Wan Jae Dong,
  • Guosong Zeng,
  • Zhengwei Ye,
  • Kai Sun,
  • Ishtiaque Ahmed Navid,
  • Baowen Zhou,
  • Francesca M. Toma,
  • Hong Guo,
  • Zetian Mi

DOI
https://doi.org/10.1038/s41467-023-37754-9
Journal volume & issue
Vol. 14, no. 1
pp. 1 – 10

Abstract

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Abstract Solar photoelectrochemical reactions have been considered one of the most promising paths for sustainable energy production. To date, however, there has been no demonstration of semiconductor photoelectrodes with long-term stable operation in a two-electrode configuration, which is required for any practical application. Herein, we demonstrate the stable operation of a photocathode comprising Si and GaN, the two most produced semiconductors in the world, for 3,000 hrs without any performance degradation in two-electrode configurations. Measurements in both three- and two-electrode configurations suggest that surfaces of the GaN nanowires on Si photocathode transform in situ into Ga-O-N that drastically enhances hydrogen evolution and remains stable for 3,000 hrs. First principles calculations further revealed that the in-situ Ga-O-N species exhibit atomic-scale surface metallization. This study overcomes the conventional dilemma between efficiency and stability imposed by extrinsic cocatalysts, offering a path for practical application of photoelectrochemical devices and systems for clean energy.