TY - JOUR
T1 - Discriminating BTX Molecules by the Nonselective Metal Oxide Sensor-Based Smart Sensing System
AU - Liu, Hongyu
AU - Meng, Gang
AU - Deng, Zanhong
AU - Nagashima, Kazuki
AU - Wang, Shimao
AU - Dai, Tiantian
AU - Li, Liang
AU - Yanagida, Takeshi
AU - Fang, Xiaodong
N1 - Funding Information:
This research was financially supported by the CAS Pioneer Hundred Talents Program from Chinese Academy of Sciences, National Natural Science Foundation of China (52025028, 11674324, and 62075223), Natural Science Foundation of Top Talent of SZTU (2020101), and CAS-JSPS Joint Research Projects (GJHZ1891). The authors thank Mr. Ning Pan and Liming Fan for partial support in the circuit design.
Publisher Copyright:
© 2021 American Chemical Society.
PY - 2021/11/26
Y1 - 2021/11/26
N2 - Discriminating structurally similar volatile organic compounds (VOCs) molecules, such as benzene, toluene, and three xylene isomers (BTX), remains a significant challenge, especially, for metal oxide semiconductor (MOS) sensors, in which selectivity is a long-standing challenge. Recent progress indicates that temperature modulation of a single MOS sensor offers a powerful route in extracting the features of adsorbed gas analytes than conventional isothermal operation. Herein, a rectangular heating waveform is applied on NiO-, WO3-, and SnO2-based sensors to gradually activate the specific gas/oxide interfacial redox reaction and generate rich (electrical) features of adsorbed BTX molecules. Upon several signal preprocessing steps, the intrinsic feature of BTX molecules can be extracted by the linear discrimination analysis (LDA) or convolutional neural network (CNN) analysis. The combination of three distinct MOS sensors noticeably benefits the recognition accuracy (with a reduced number of training iterations). Finally, a prototype of a smart BTX recognition system (including sensing electronics, sensors, Wi-Fi module, UI, PC, etc.) based on temperature modulation has been explored, which enables a prompt, accurate, and stable identification of xylene isomers in the ambient air background and raises the hope of innovating the future advanced machine olfactory system.
AB - Discriminating structurally similar volatile organic compounds (VOCs) molecules, such as benzene, toluene, and three xylene isomers (BTX), remains a significant challenge, especially, for metal oxide semiconductor (MOS) sensors, in which selectivity is a long-standing challenge. Recent progress indicates that temperature modulation of a single MOS sensor offers a powerful route in extracting the features of adsorbed gas analytes than conventional isothermal operation. Herein, a rectangular heating waveform is applied on NiO-, WO3-, and SnO2-based sensors to gradually activate the specific gas/oxide interfacial redox reaction and generate rich (electrical) features of adsorbed BTX molecules. Upon several signal preprocessing steps, the intrinsic feature of BTX molecules can be extracted by the linear discrimination analysis (LDA) or convolutional neural network (CNN) analysis. The combination of three distinct MOS sensors noticeably benefits the recognition accuracy (with a reduced number of training iterations). Finally, a prototype of a smart BTX recognition system (including sensing electronics, sensors, Wi-Fi module, UI, PC, etc.) based on temperature modulation has been explored, which enables a prompt, accurate, and stable identification of xylene isomers in the ambient air background and raises the hope of innovating the future advanced machine olfactory system.
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U2 - 10.1021/acssensors.1c01704
DO - 10.1021/acssensors.1c01704
M3 - Article
C2 - 34735117
AN - SCOPUS:85119150200
SN - 2379-3694
VL - 6
SP - 4167
EP - 4175
JO - ACS Sensors
JF - ACS Sensors
IS - 11
ER -