4.8 Article

Rationally constructed ZnCdS-HDCs@In2S3-HNRs double-hollow heterojunction with promoted light capture capability for photoelectrochemical biosensing

期刊

BIOSENSORS & BIOELECTRONICS
卷 201, 期 -, 页码 -

出版社

ELSEVIER ADVANCED TECHNOLOGY
DOI: 10.1016/j.bios.2021.113957

关键词

Double-hollow heterojunction; ZnCdS@In2S3; PEC biosensors; CA15-3

资金

  1. Guangdong Basic and Applied Basic Research Foundation [2019A1515010618]
  2. Guangdong Special Funds for the Science & Technology Project [2019ST029, 2019ST089]
  3. Ka Shing Foundation Cross-Disciplinary Research Grant [2020LKSFG06C]

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In this study, a novel heterojunction was constructed to enhance the photoelectrochemical performance and detect CA15-3. The mechanism of how In2S3-HNRs improve photochemical properties under visible light was elucidated, and the working mechanism of the novel heterojunction was revealed.
The construction of novel heterojunction is regarded as an operative scheme to promote the transport of photogenerated carriers and reduce electron-hole pair recombination to enhance the photoelectrochemical (PEC) performances. Herein, ZnCdS hollow dodecahedral nanocages (ZnCdS-HDCs) and In2S3 hollow nanorods (In2S3- HNRs), which were derived from two different of metal-organic frameworks (MOFs) by solvothermal sulfidation method and were constructed an original double-hollow heterostructure ZnCdS-HDCs@In2S3-HNRs. The intrinsic mechanism of In2S3-HNRs benefiting from unique morphology to boost the photochemical properties under visible light irradiation was illustrated. Meanwhile, the mechanism of the novel type II heterojunction with staggered matching levels was revealed, which could effectively restrict electron-hole pair reassociation separation, and accelerated charge separation and transfer. Therefore, based on the excellent PEC performance of ZnCdS-HDCs@In2S3-HNRs double-hollow heterostructure, a signal-off PEC biosensor platform without labeled was constructed for the detection of CA15-3, which manifested acceptable specificity, reproducibility and stability. Additionally, the expected PEC biosensors showed a linear response range from 1.0 x 10(-5) to 10 U.mL(-1) in addition to an ultralow detection limit of 3.78 x 10(-6) U.mL(-1). This study innovatively constructed and prepared a new double-hollow heterojunction material with superior PEC nature for the application of PEC biosensing, which exhibits a broad application prospect.

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