Nature Communications (Dec 2023)

Sub-50 nm perovskite-type tantalum-based oxynitride single crystals with enhanced photoactivity for water splitting

  • Jiadong Xiao,
  • Mamiko Nakabayashi,
  • Takashi Hisatomi,
  • Junie Jhon M. Vequizo,
  • Wenpeng Li,
  • Kaihong Chen,
  • Xiaoping Tao,
  • Akira Yamakata,
  • Naoya Shibata,
  • Tsuyoshi Takata,
  • Yasunobu Inoue,
  • Kazunari Domen

DOI
https://doi.org/10.1038/s41467-023-43838-3
Journal volume & issue
Vol. 14, no. 1
pp. 1 – 9

Abstract

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Abstract A long-standing trade-off exists between improving crystallinity and minimizing particle size in the synthesis of perovskite-type transition-metal oxynitride photocatalysts via the thermal nitridation of commonly used metal oxide and carbonate precursors. Here, we overcome this limitation to fabricate ATaO2N (A = Sr, Ca, Ba) single nanocrystals with particle sizes of several tens of nanometers, excellent crystallinity and tunable long-wavelength response via thermal nitridation of mixtures of tantalum disulfide, metal hydroxides (A(OH)2), and molten-salt fluxes (e.g., SrCl2) as precursors. The SrTaO2N nanocrystals modified with a tailored Ir–Pt alloy@Cr2O3 cocatalyst evolved H2 around two orders of magnitude more efficiently than the previously reported SrTaO2N photocatalysts, with a record solar-to-hydrogen energy conversion efficiency of 0.15% for SrTaO2N in Z-scheme water splitting. Our findings enable the synthesis of perovskite-type transition-metal oxynitride nanocrystals by thermal nitridation and pave the way for manufacturing advanced long-wavelength-responsive particulate photocatalysts for efficient solar energy conversion.