Formation of nanograined Ag-Co3O4 core@shell structure to achieve enhanced xylene sensing characteristics

Xylene (C8H10) is a volatile organic compound as well as a pollutant which needs to be detected for various demands and applications. Herein, we report a unique core@shell (C-S) structure with core noble metal particles to incorporate catalytic elemnts. A nanograined Ag-Co3O4 C-S structure was prepa...

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Published in:Sensors and actuators. B, Chemical Chemical, 2023-10, Vol.392, p.134049, Article 134049
Main Authors: Shin, Ka Yoon, Mirzaei, Ali, Lee, Ha Young, Bang, Jae Hoon, Oum, Wansik, Kim, Eun Bi, Kim, Hyeong Min, Majhi, Sanjit Manohar, Kim, Sang Sub, Kim, Hyoun Woo
Format: Article
Language:English
Subjects:
Ag-Co3O4 core@shell
Gas sensor
Nanograined
Sensing mechanism
Xylene
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Summary:Xylene (C8H10) is a volatile organic compound as well as a pollutant which needs to be detected for various demands and applications. Herein, we report a unique core@shell (C-S) structure with core noble metal particles to incorporate catalytic elemnts. A nanograined Ag-Co3O4 C-S structure was prepared using a chemical synthesis method. Systematic xylene sensing studies were undertaken to prove the excellence of nanograined C-S structure. Various characterization techniques were used to confirm the synthesis of desired products with the expected features. The pristine sensor offered the highest performance to xylene at 350 °C, whereas nanograined Ag-Co3O4 C-S structure gas sensor worked at a lower temperature namely 250 °C. In addition, the maximum response of the pristine sensor to 50 ppm-xylene was about 1.26, whereas that of the nanograined Ag-Co3O4 C-S structure gas sensor was 2.47. Moreover, the latter sensor showed higher selectivity to xylene than the former sensor. The improved xylene sensing characteristics of the nanograined Ag-Co3O4 C-S structure gas sensor were caused by its high surface area, formation of Ag-Co3O4 heterojunctions, and catalytic effects of Ag nanoparticles. This study demonstrates the potential of this new system for sensing of xylene. [Display omitted] •Synthesis of nanograined Ag-Co3O4 core@shell structures for Xylene sensing studies.•Decrease of optimal temperature for Ag@Co3O4 with enhanced sensing performance.•Nanograined Ag-Co3O4 core@shell showed a response of 2.47–50 ppm xylene at 250 °C.•Xylene sensing mechanism by Ag-Co3O4 heterojunctions and catalytic effect of Ag.
ISSN:0925-4005
1873-3077
DOI:10.1016/j.snb.2023.134049