Strong evidence for interface-field-induced photocarrier separation in new AgFeO2-BiVO4 heterostructures and their efficient photo-Fenton degradation of ciprofoxacin

[Display omitted] •AgFeO2-BiVO4 heterostructured photocatalysts were developed by decorating AgFeO2 NPs onto BiVO4 nanobricks.•The heterostructures exhibit much enhanced photo-Fenton degradation of CIP.•Experimental and theoretical evidences corroborate the interface field formation, photocarrier di...

Full description

Saved in:
Bibliographic Details
Published in:Applied surface science 2025-01, Vol.679, p.161275, Article 161275
Main Authors: Ma, Qianfei, Ren, Jiale, Sun, Xiaofeng, Chen, Xiujuan, Liu, Guorong, Wang, Shifa, Yang, Hua
Format: Article
Language:English
Subjects:
Advanced characterization techniques
BiVO4-AgFeO2 heterostructures
Photocatalysis mechanisms
Photodegradation of CIP
Theoretical calculations
Citations: Items that this one cites
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:[Display omitted] •AgFeO2-BiVO4 heterostructured photocatalysts were developed by decorating AgFeO2 NPs onto BiVO4 nanobricks.•The heterostructures exhibit much enhanced photo-Fenton degradation of CIP.•Experimental and theoretical evidences corroborate the interface field formation, photocarrier dissociation and transfer.•The photocatalytic mechanism of the heterostructures were deeply elucidated.•Degradation pathways of CIP and potential toxicity of degradation by-products were investigated. Deep elucidation of photocarrier transfer and separation mechanism is scientifically significant for developing new photocatalysts in pollutant elimination. In this study, we have immobilized AgFeO2 (AFO) nanoparticles on the surface of BiVO4 (BVO) nanobricks to construct new BVO-AFO heterostructured photocatalysts. Multiple advanced characterization techniques combined with theoretical calculations corroborate substantial evidence for the formation of built-in electric field at the BVO-AFO heterojunction interface and efficient photocarrier transfer/separation behavior and mechanism. Simulated-sunlight-driven photodegradation of ciprofoxacin (CIP) demonstrates an important enhanced photocatalysis of the heterostructure photocatalysts; particularly, the BVO-15 %AFO exhibits a photodegradation performance with η(30 min) = 89.9 % and kapp = 0.06659 min−1, which is enhanced by 4.2 (or 3.4) times over that of bare BVO (or AFO). The heterostructure-enhanced photocatalysis is benefited from the interface-field-facilitated transfer and separation of photocarriers, thus extending their lifetime and making them more probable to participate in the photocatalytic reactions. Furthermore, the BVO-AFO heterostructured photocatalysts demonstrate an important activation of peroxymonosulfate (PMS) or H2O2 to generate additional •OH and •SO4− reactive species, thus further promoting the CIP degradation. This work provides an important scientific basis for designing excellent heterostructured photocatalysts.
ISSN:0169-4332
DOI:10.1016/j.apsusc.2024.161275