Fabrication of the Fe2O3:ZnO Based Nanostructured Sensor for LPG Detection

This study aimed to develop a high-performance liquefied petroleum gas (LPG) sensor based on the Fe2O3:ZnO material. A solid-state synthesis of the ceramic target with Fe2O3 and ZnO nanopowders is presented. LPG sensing nanostructured films were obtained by the high-frequency magnetron sputtering me...

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Veröffentlicht in:	E-journal of surface science and nanotechnology 2024/03/09, Vol.22(2), pp.149-156
Hauptverfasser:	Aleksanyan, Mikayel, Sayunts, Artak, Shahkhatuni, Gevorg, Shahnazaryan, Gohar, Simonyan, Zarine, Kananov, Davit
Format:	Artikel
Sprache:	eng ; jpn
Schlagworte:	Crystallography Electron microscopes Electron microscopy Gas sensors Liquefied petroleum gas Low concentrations Low temperature LPG Magnetic properties Magnetron sputtering Metal oxide Nanostructure Operating temperature Parameters Recovery Sensor Sensors Thickness measurement Thin film Thin films Zinc oxide
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container_title	E-journal of surface science and nanotechnology
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creator	Aleksanyan, Mikayel Sayunts, Artak Shahkhatuni, Gevorg Shahnazaryan, Gohar Simonyan, Zarine Kananov, Davit
description	This study aimed to develop a high-performance liquefied petroleum gas (LPG) sensor based on the Fe2O3:ZnO material. A solid-state synthesis of the ceramic target with Fe2O3 and ZnO nanopowders is presented. LPG sensing nanostructured films were obtained by the high-frequency magnetron sputtering method. The thickness and surface morphology of the sensing layers were determined by thickness measuring profilometer and scanning electron microscope, respectively. The crystallographic properties and elemental mapping analysis of the Fe2O3:ZnO material were investigated by transmission electron microscopy. Energy-dispersive X-ray elementary analysis highlighted the presence of single elements available in the Fe2O3:ZnO material. Further, a chemo-resistive sensor based on a thin film of the Fe2O3:ZnO nanostructure was fabricated onto the Multi-Sensor-Platform, and its gas sensing properties were investigated towards LPG. The sensor with Pd catalytic particles showed the highest gas response at 200°C. The LPG sensing parameters like sensor response and response/recovery times were investigated at different operating temperatures. The minimum response and recovery times of the sensor corresponding to an LPG concentration of 2000 ppm were found to be 26 and 15 s, respectively. The investigated sensing parameters demonstrate that the fabricated LPG sensor based on the Fe2O3:ZnO semiconductor nanostructures is challenging for the detection of low concentrations of LPG at relatively low temperatures.
doi_str_mv	10.1380/ejssnt.2024-008
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A solid-state synthesis of the ceramic target with Fe2O3 and ZnO nanopowders is presented. LPG sensing nanostructured films were obtained by the high-frequency magnetron sputtering method. The thickness and surface morphology of the sensing layers were determined by thickness measuring profilometer and scanning electron microscope, respectively. The crystallographic properties and elemental mapping analysis of the Fe2O3:ZnO material were investigated by transmission electron microscopy. Energy-dispersive X-ray elementary analysis highlighted the presence of single elements available in the Fe2O3:ZnO material. Further, a chemo-resistive sensor based on a thin film of the Fe2O3:ZnO nanostructure was fabricated onto the Multi-Sensor-Platform, and its gas sensing properties were investigated towards LPG. The sensor with Pd catalytic particles showed the highest gas response at 200°C. The LPG sensing parameters like sensor response and response/recovery times were investigated at different operating temperatures. The minimum response and recovery times of the sensor corresponding to an LPG concentration of 2000 ppm were found to be 26 and 15 s, respectively. 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Surf. Sci. Nanotechnol.</addtitle><description>This study aimed to develop a high-performance liquefied petroleum gas (LPG) sensor based on the Fe2O3:ZnO material. A solid-state synthesis of the ceramic target with Fe2O3 and ZnO nanopowders is presented. LPG sensing nanostructured films were obtained by the high-frequency magnetron sputtering method. The thickness and surface morphology of the sensing layers were determined by thickness measuring profilometer and scanning electron microscope, respectively. The crystallographic properties and elemental mapping analysis of the Fe2O3:ZnO material were investigated by transmission electron microscopy. Energy-dispersive X-ray elementary analysis highlighted the presence of single elements available in the Fe2O3:ZnO material. Further, a chemo-resistive sensor based on a thin film of the Fe2O3:ZnO nanostructure was fabricated onto the Multi-Sensor-Platform, and its gas sensing properties were investigated towards LPG. 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Surf. Sci. Nanotechnol.</addtitle><date>2024-03-09</date><risdate>2024</risdate><volume>22</volume><issue>2</issue><spage>149</spage><epage>156</epage><pages>149-156</pages><artnum>2024-008</artnum><issn>1348-0391</issn><eissn>1348-0391</eissn><abstract>This study aimed to develop a high-performance liquefied petroleum gas (LPG) sensor based on the Fe2O3:ZnO material. A solid-state synthesis of the ceramic target with Fe2O3 and ZnO nanopowders is presented. LPG sensing nanostructured films were obtained by the high-frequency magnetron sputtering method. The thickness and surface morphology of the sensing layers were determined by thickness measuring profilometer and scanning electron microscope, respectively. The crystallographic properties and elemental mapping analysis of the Fe2O3:ZnO material were investigated by transmission electron microscopy. Energy-dispersive X-ray elementary analysis highlighted the presence of single elements available in the Fe2O3:ZnO material. 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subjects	Crystallography Electron microscopes Electron microscopy Gas sensors Liquefied petroleum gas Low concentrations Low temperature LPG Magnetic properties Magnetron sputtering Metal oxide Nanostructure Operating temperature Parameters Recovery Sensor Sensors Thickness measurement Thin film Thin films Zinc oxide
title	Fabrication of the Fe2O3:ZnO Based Nanostructured Sensor for LPG Detection
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