Issue 5, 2023

CaIn2S4–In2O3 hybrid nanofibers with expedited photocarrier separation for fast photocatalytic bacterial inactivation under visible light

Abstract

Semiconductor heterostructures are of critical importance in steering the flow of photocarriers (i.e. e and h+). Here, we have fabricated heterostructure-based semiconductor fibers comprising electrospun In2O3 nanofibers coaxially wrapped by CaIn2S4 nanofoils. The hybrid fibers are characterized by a strong interplay between CaIn2S4 and In2O3, enabling fast photocarrier separation to generate copious reactive species for disinfection. When illuminated by visible light (λ ≥ 400 nm), the hybrid fibers deliver exceptionally high photocatalytic activity for bacterial inactivation (7 log-reduction in viable cell count for 20 min), well-outcompeting the parent compounds, CaIn2S4–In2O3 mixtures, and many active photocatalysts reported. The hybrid fibers are type-II semiconductor heterojunctions in nature that can enrich photogenerated e and h+ at the different components of the hybrid fibers. This work justifies the importance of semiconductor heterostructures in guiding photocarrier flows and offers a paradigm for the design of semiconductor hybrid fibers in the area of photocatalytic bacterial inactivation.

Graphical abstract: CaIn2S4–In2O3 hybrid nanofibers with expedited photocarrier separation for fast photocatalytic bacterial inactivation under visible light

Supplementary files

Article information

Article type
Research Article
Submitted
20 Dec 2022
Accepted
31 Jan 2023
First published
01 Feb 2023

Inorg. Chem. Front., 2023,10, 1650-1659

CaIn2S4–In2O3 hybrid nanofibers with expedited photocarrier separation for fast photocatalytic bacterial inactivation under visible light

L. Wang, Z. Wan, X. Xu and J. Qian, Inorg. Chem. Front., 2023, 10, 1650 DOI: 10.1039/D2QI02694E

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