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Nanoparticulate TiN Loading to Promote Z-Scheme Water Splitting Using a Narrow-Bandgap Nonoxide-Based Photocatalyst Sheet.

Rhauane Almeida GalvãoSwarnava NandyAkio HirakoTakehiro OtsukiMamiko NakabayashiDaling LuTakashi HisatomiKazunari Domen
Published in: Small (Weinheim an der Bergstrasse, Germany) (2024)
Some oxide-based particulate photocatalyst sheets exhibit excellent activity during the water-splitting reaction. The replacement of oxide photocatalysts with narrow-bandgap photocatalysts based on nonoxides could provide the higher solar-to-hydrogen energy conversion efficiencies that are required for practical implementation. Unfortunately, the activity of nonoxide-based photocatalyst sheets is low in many cases, indicating the need for strategies to improve the quality of nonoxide photocatalysts and the charge transfer process. In this work, single-crystalline particulate SrTaO 2 N is studied as an oxygen evolution photocatalyst for photocatalyst sheets applied to Z-scheme water splitting, in combination with La 5 Ti 2 Cu 0.9 Ag 0.1 O 7 S 5 and Au as the hydrogen evolution photocatalyst and conductive layer, respectively. The loading of SrTaO 2 N with CoO x provided increases activity during photocatalytic water oxidation, giving an apparent quantum yield of 15.7% at 420 nm. A photocatalyst sheet incorporating CoO x -loaded SrTaO 2 N is also found to promote Z-scheme water splitting under visible light. Notably, the additional loading of nanoparticulate TiN on the CoO x -loaded SrTaO 2 N improves the water splitting activity by six times because the TiN promotes electron transfer from the SrTaO 2 N particles to the Au layer. This work demonstrates key concepts related to the improvement of nonoxide-based photocatalyst sheets based on facilitating the charge transfer process through appropriate surface modifications.
Keyphrases
  • visible light
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  • electron transfer
  • healthcare
  • oxide nanoparticles
  • magnetic resonance imaging
  • cancer therapy
  • nitric oxide
  • photodynamic therapy
  • hydrogen peroxide
  • solid state