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Nanoscale

Title:		Rare-earth-doped indium oxide nanosphere-based gas sensor for highly sensitive formaldehyde detection at a low temperature
Author(s):		Ma X; Zhu H; Yu L; Li X; Ye E; Li Z; Loh XJ; Wang S;
Address:		"Guangdong Provincial Key Laboratory of Petrochemical Pollution Process and Control, School of Environmental Science and Engineering, Guangdong University of Petrochemical Technology, Maoming, Guangdong 525000, China. Institute of Materials Research and Engineering, A*STAR (Agency for Science, Technology and Research), Singapore 138634. Institute of Sustainability for Chemicals, Energy and Environment (ISCE2) A*STAR (Agency for Science, Technology and Research), Singapore 138634"
Journal Title:		Nanoscale
Year:		2023
Volume:		20230127
Issue:		4
Page Number:		1609 - 1618
DOI:		10.1039/d2nr04972d
ISSN/ISBN:		2040-3372 (Electronic) 2040-3364 (Linking)
Abstract:		"Formaldehyde (HCHO) is widely viewed as a carcinogenic volatile organic compound in indoor air pollution that can seriously threaten human health and life. Thus, there is a critical need to develop gas sensors with improved sensing performance, including outstanding selectivity, low operating temperature, high responsiveness, and short recovery time, for HCHO detection. Currently, doping is considered an effective strategy to raise the sensing performance of gas sensors. Herein, various rare earth elements-doped indium oxide (RE-In(2)O(3)) nanospheres were fabricated as gas sensors for improved HCHO detection via a facile and environmentally solvothermal method. Such RE-In(2)O(3) nanosphere-based sensors exhibited remarkable gas-sensing performance, including a high selectivity and stability in air. Compared with pure, Yb-, Dy-doped In(2)O(3) and different La ratios doped into In(2)O(3), 6% La-doped In(2)O(3) (La-In(2)O(3)) nanosphere-based sensors demonstrated a high response value of 210 to 100 ppm at 170 degrees C, which was around 16 times higher than that of the pure In(2)O(3) sensor, and also exhibited a detection limit of 10.9 ppb, and a response time of 30 s to 100 ppm HCHO with a recovery time of 160 s. Finally, such superior sensing performance of the 6% La-In(2)O(3) sensors was proposed to be attributed to the synergistic effect of the large specific surface area and enhanced surface oxygen vacancies on the surface of In(2)O(3) nanospheres, which produced chemisorbed oxygen species to release electrons and provided abundant reaction sites for HCHO gas. This study sheds new light on designing nanomaterials to build gas sensors for HCHO detection"
Keywords:
Notes:		"PubMed-not-MEDLINEMa, Xiangyun Zhu, Houjuan Yu, Long Li, Xin Ye, Enyi Li, Zibiao Loh, Xian Jun Wang, Suhua eng England 2023/01/06 Nanoscale. 2023 Jan 27; 15(4):1609-1618. doi: 10.1039/d2nr04972d"