Details

Autor(en) / Beteiligte

• Chen, Runyu
• Meng, Linxing
• Wang, Changda
• Xu, Weiwei
• Huang, Yulong
• Song, Li
• Li, Liang

Titel

Nonstoichiometric In–S group yielding efficient carrier transfer pathway in In2S3 photoanode for solar water oxidation

Ist Teil von

• SusMat (Online), 2024-02, Vol.4 (1), p.154-165

Ort / Verlag

Wiley

Erscheinungsjahr

2024

Quelle

Elektronische Zeitschriftenbibliothek - Frei zugängliche E-Journals

Beschreibungen/Notizen

• The construction of high‐efficiency photoanodes is essential for developing outstanding photoelectrochemical (PEC) water splitting cells. Furthermore, insufficient carrier transport capabilities and sluggish surface water oxidation kinetics limit its application. Using a solvothermal annealing strategy, we prepared a nonstoichiometric In–S (NS) group on the surface of an In2S3 photoanode in situ and unexpectedly formed a type II transfer path of carrier, thereby reducing the interfacial recombination and promoting the bulk separation. First‐principles calculations and comprehensive characterizations demonstrated NS group as an excellent oxygen evolution cocatalyst (OEC) that effectively facilitated carrier transport, lowered the surface overpotential, increased the surface active site, and accelerated the surface oxygen evolution reaction kinetics by precisely altering the rate‐determining steps of * to *OH and *O to *OOH. These synergistic effects remarkably enhanced the PEC performance, with a high photocurrent density of 5.02 mA cm−2 at 1.23 V versus reversible hydrogen electrode and a negative shift in the onset potential by 310 mV. This work provides a new strategy for the in situ preparation of high‐efficiency OECs and provides ideas for constructing excellent carrier transfer and transport channels. A facile solvothermal annealing strategy is utilized to prepare nonstoichiometric In–S groups on the surface of an In2S3 photoanode in situ. The hybridized photoanode displays efficient carrier bulk transport due to the unexpected type II heterojunction and the enhanced surface oxygen evolution reaction kinetics, largely boosting the photoelectrochemical performance and demonstrating a new surface nonstoichiometric modification method to promote carrier transport dynamics with potential broad applications in water splitting and catalysis.