| Literature DB >> 26484799 |
Guohui Chen1, Shaozheng Ji1, Haidong Li1, Xueliang Kang1, Sujie Chang1, Yana Wang1, Guangwei Yu1, Jianren Lu2, Jerome Claverie3, Yuanhua Sang1, Hong Liu1,4.
Abstract
A SnO2 gas sensor was prepared by a two-step oxidation process whereby a Sn(II) precursor was partially oxidized by a hydrothermal process and the resulting Sn3O4 nanoplates were thermally oxidized to yield SnO2 nanoplates. The SnO2 sensor was selective and responsive toward ethanol at a temperature as low as 43 °C. This low sensing temperature stems from the rapid charge transport within SnO2 and from the presence of high-energy (001) facets available for oxygen chemisorption. SnO2/TiO2 nanobelt heterostructures were fabricated by a similar two-step process in which TiO2 nanobelts acted as support for the epitaxial growth of intermediate Sn3O4. At temperatures ranging from 43 to 276 °C, the response of these branched nanobelts is more than double the response of SnO2 for ethanol detection. Our observations demonstrate the potential of low-cost SnO2-based sensors with controlled morphology and reactive facets for detecting gases around room temperature.Entities:
Keywords: SnO2 nanoplates; TiO2 nanobelts; ethanol; heterostructure; high energy facet; room temperature sensor
Year: 2015 PMID: 26484799 DOI: 10.1021/acsami.5b08630
Source DB: PubMed Journal: ACS Appl Mater Interfaces ISSN: 1944-8244 Impact factor: 9.229