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Article Abstract
Ethylene is a crucial raw material for the production of chemical products, and thus, the development of high-performance ethylene (CH) gas sensors has garnered significant interest for achieving reliable CH monitoring. In this article, MnO nanorods and Pt-modified MnO nanorods were prepared using hydrothermal and reduction methods. The samples were characterized using X-ray diffractometer (XRD), field emission scanning electron microscopy (FESEM), transmission electron microscope (TEM), and XPS techniques. The ethylene gas-sensing performance of Pt/MnO and pure MnO was compared, and the material exhibited excellent ethylene gas-sensing performance when the Pt loading was 3 atom %. After loading Pt, the optimal operating temperature of MnO decreased from 360 to 180 °C. The synthesized 3 atom % Pt/MnO nanocomposite not only exhibited a maximum response value of 7.4-1000 ppm of CH at 180 °C but also demonstrated excellent selectivity and good repeatability. The improvement in CH gas-sensing performance by Pt nanoparticles is primarily attributed to the synergistic effects of spillover and the nanoSchottky barrier. Current reports of vinyl sensors, with their high operating temperatures and low response values, still fail to meet real-time monitoring requirements, and this work enables the realization of a material that exhibits higher response values at low temperatures, providing a promising material for industrial process monitoring.
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| http://dx.doi.org/10.1021/acs.langmuir.5c02091 | DOI Listing |
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