AI Article Synopsis

  • - The study focuses on interfacial charge-transfer transitions (ICTTs) between organic compounds (like benzoic acid derivatives) and inorganic semiconductors, specifically exploring their potential uses in solar energy and chemical sensing.
  • - Research highlights the first observation of ICTTs in SnO nanoparticles, which absorb visible light when treated with specific organic molecules, showing that the absorption characteristics vary based on the substituent groups in the molecules.
  • - The findings indicate that the absorption band results from charge transfer from the highest occupied molecular orbital (HOMO) of the organic compounds to the conduction band of SnO, providing insights that could advance fundamental research and practical applications in the field.

Article Abstract

Interfacial charge-transfer transitions (ICTTs) between organic compounds and inorganic semiconductors have recently attracted increasing attention for their potential applications in solar energy conversions and chemical sensing due to the unique functions of visible-light absorption with colourless organic molecules and direct charge separation. However, inorganic semiconductors available for ICTT are quite limited to a few kinds of metal-oxide semiconductors (TiO, ZnO, ). Particularly, the exploration of ICTT in inorganic semiconductors with a lower-energy conduction band such as SnO is an important issue for realizing a wide range of visible-light absorption for organic adsorbates with the deep highest occupied molecular orbital (HOMO) such as benzoic acid derivatives. Here, we report the first observation of ICTT in SnO. SnO nanoparticles show a broad absorption band in the visible region by chemisorption of 4-dimethylaminobenzoic acid (4-DMABA) and 4-aminobenzoic acid (4-ABA)) the carboxylate group. The wavelength range of the ICTT band significantly changes depending on the kind of substituent group. The ionization potential measurement and density functional theory (DFT) analysis reveal that the absorption band is attributed to ICTT from the HOMO of the adsorbed benzoic acid derivatives to the conduction band of SnO. In addition, we clarify the mechanism of ICTT in SnO computationally. Our research opens up a way to the fundamental research on ICTT in SnO and applications in solar energy conversions and chemical sensing.

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Source
http://www.ncbi.nlm.nih.gov/pmc/articles/PMC9033968PMC
http://dx.doi.org/10.1039/d1ra03422gDOI Listing

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