Fabrication of a Micro-Electromechanical System-Based Acetone Gas Sensor Using CeO2 Nanodot-Decorated WO3 Nanowires
Preparation of reliable, stable, and highly responsive gas-sensing devices for the detection of acetone has been considered to be a key issue for the development of accurate disease diagnosis systems via exhaled breath. In this paper, novel CeO2 nanodot-decorated WO3 nanowires are successfully synth...
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| Published in | ACS applied materials & interfaces Vol. 12; no. 12; pp. 14095 - 14104 |
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| Main Authors | , , , , , , , , , |
| Format | Journal Article |
| Language | English |
| Published |
American Chemical Society
25.03.2020
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| Subjects | |
| Online Access | Get full text |
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| Abstract | Preparation of reliable, stable, and highly responsive gas-sensing devices for the detection of acetone has been considered to be a key issue for the development of accurate disease diagnosis systems via exhaled breath. In this paper, novel CeO2 nanodot-decorated WO3 nanowires are successfully synthesized through a sequential hydrothermal and thermolysis process. Such CeO2 nanodot-decorated WO3 nanowires exhibited a remarkable enhancement in acetone-sensing performance based on a miniaturized micro-electromechanical system device, which affords high response (S = 1.30–500 ppb, 1.62–2.5 ppm), low detection limit (500 ppb), and superior selectivity toward acetone. The improved performance of the acetone sensor is likely to be originated from the fast carrier transportation of WO3 nanowires, the formation of WO3–CeO2 heterojunctions, and the existence of large amounts of oxygen vacancies in CeO2. The improved reaction thermodynamics and sensing mechanisms have also been revealed by the specific band alignment and X-ray photoelectron spectroscopy analysis. |
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| AbstractList | Preparation of reliable, stable, and highly responsive gas-sensing devices for the detection of acetone has been considered to be a key issue for the development of accurate disease diagnosis systems via exhaled breath. In this paper, novel CeO2 nanodot-decorated WO3 nanowires are successfully synthesized through a sequential hydrothermal and thermolysis process. Such CeO2 nanodot-decorated WO3 nanowires exhibited a remarkable enhancement in acetone-sensing performance based on a miniaturized micro-electromechanical system device, which affords high response (S = 1.30–500 ppb, 1.62–2.5 ppm), low detection limit (500 ppb), and superior selectivity toward acetone. The improved performance of the acetone sensor is likely to be originated from the fast carrier transportation of WO3 nanowires, the formation of WO3–CeO2 heterojunctions, and the existence of large amounts of oxygen vacancies in CeO2. The improved reaction thermodynamics and sensing mechanisms have also been revealed by the specific band alignment and X-ray photoelectron spectroscopy analysis. Preparation of reliable, stable, and highly responsive gas-sensing devices for the detection of acetone has been considered to be a key issue for the development of accurate disease diagnosis systems via exhaled breath. In this paper, novel CeO2 nanodot-decorated WO3 nanowires are successfully synthesized through a sequential hydrothermal and thermolysis process. Such CeO2 nanodot-decorated WO3 nanowires exhibited a remarkable enhancement in acetone-sensing performance based on a miniaturized micro-electromechanical system device, which affords high response (S = 1.30-500 ppb, 1.62-2.5 ppm), low detection limit (500 ppb), and superior selectivity toward acetone. The improved performance of the acetone sensor is likely to be originated from the fast carrier transportation of WO3 nanowires, the formation of WO3-CeO2 heterojunctions, and the existence of large amounts of oxygen vacancies in CeO2. The improved reaction thermodynamics and sensing mechanisms have also been revealed by the specific band alignment and X-ray photoelectron spectroscopy analysis.Preparation of reliable, stable, and highly responsive gas-sensing devices for the detection of acetone has been considered to be a key issue for the development of accurate disease diagnosis systems via exhaled breath. In this paper, novel CeO2 nanodot-decorated WO3 nanowires are successfully synthesized through a sequential hydrothermal and thermolysis process. Such CeO2 nanodot-decorated WO3 nanowires exhibited a remarkable enhancement in acetone-sensing performance based on a miniaturized micro-electromechanical system device, which affords high response (S = 1.30-500 ppb, 1.62-2.5 ppm), low detection limit (500 ppb), and superior selectivity toward acetone. The improved performance of the acetone sensor is likely to be originated from the fast carrier transportation of WO3 nanowires, the formation of WO3-CeO2 heterojunctions, and the existence of large amounts of oxygen vacancies in CeO2. The improved reaction thermodynamics and sensing mechanisms have also been revealed by the specific band alignment and X-ray photoelectron spectroscopy analysis. Preparation of reliable, stable, and highly responsive gas-sensing devices for the detection of acetone has been considered to be a key issue for the development of accurate disease diagnosis systems via exhaled breath. In this paper, novel CeO₂ nanodot-decorated WO₃ nanowires are successfully synthesized through a sequential hydrothermal and thermolysis process. Such CeO₂ nanodot-decorated WO₃ nanowires exhibited a remarkable enhancement in acetone-sensing performance based on a miniaturized micro-electromechanical system device, which affords high response (S = 1.30–500 ppb, 1.62–2.5 ppm), low detection limit (500 ppb), and superior selectivity toward acetone. The improved performance of the acetone sensor is likely to be originated from the fast carrier transportation of WO₃ nanowires, the formation of WO₃–CeO₂ heterojunctions, and the existence of large amounts of oxygen vacancies in CeO₂. The improved reaction thermodynamics and sensing mechanisms have also been revealed by the specific band alignment and X-ray photoelectron spectroscopy analysis. |
| Author | Wang, Yuan-Yuan Lu, Hong-Liang Cao, Qi Li, Xiao-Xi Huang, Wei Yuan, Kaiping Yang, Jia-He Zhang, David Wei Wang, Cheng-Yu Zhu, Li-Yuan |
| AuthorAffiliation | Southeast University Fudan University Department of Electronic Engineering Key Laboratory of Energy Thermal Conversion and Control of Ministry of Education, School of Energy and Environment State Key Laboratory of ASIC and System, School of Microelectronics |
| AuthorAffiliation_xml | – name: State Key Laboratory of ASIC and System, School of Microelectronics – name: Fudan University – name: Department of Electronic Engineering – name: Southeast University – name: Key Laboratory of Energy Thermal Conversion and Control of Ministry of Education, School of Energy and Environment |
| Author_xml | – sequence: 1 givenname: Kaiping surname: Yuan fullname: Yuan, Kaiping organization: Fudan University – sequence: 2 givenname: Cheng-Yu surname: Wang fullname: Wang, Cheng-Yu organization: Fudan University – sequence: 3 givenname: Li-Yuan surname: Zhu fullname: Zhu, Li-Yuan organization: Fudan University – sequence: 4 givenname: Qi surname: Cao fullname: Cao, Qi organization: Southeast University – sequence: 5 givenname: Jia-He surname: Yang fullname: Yang, Jia-He organization: Fudan University – sequence: 6 givenname: Xiao-Xi surname: Li fullname: Li, Xiao-Xi organization: Fudan University – sequence: 7 givenname: Wei surname: Huang fullname: Huang, Wei organization: Fudan University – sequence: 8 givenname: Yuan-Yuan surname: Wang fullname: Wang, Yuan-Yuan organization: Southeast University – sequence: 9 givenname: Hong-Liang orcidid: 0000-0003-2398-720X surname: Lu fullname: Lu, Hong-Liang email: honglianglu@fudan.edu.cn organization: Fudan University – sequence: 10 givenname: David Wei surname: Zhang fullname: Zhang, David Wei organization: Fudan University |
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| SubjectTerms | acetone ceric oxide detection limit disease diagnosis nanowires oxygen thermal degradation thermodynamics tungsten oxide X-ray photoelectron spectroscopy |
| Title | Fabrication of a Micro-Electromechanical System-Based Acetone Gas Sensor Using CeO2 Nanodot-Decorated WO3 Nanowires |
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