Facile synthesis of titania nanowires via a hot filament method and conductometric measurement of their response to hydrogen sulfide gas

Martin Munz, Mark T. Langridge, Kishore K. Devarepally, David C. Cox, Pravin Patel, Nicholas A. Martin, Gergely Vargha, Vlad Stolojan, Sam White, Richard J. Curry

Research output: Contribution to journalArticlepeer-review

28 Scopus citations

Abstract

Titania nanostructures are of increasing interest for a variety of applications, including photovoltaics, water splitting, and chemical sensing. Because of the photocatalytical properties of TiO2, chemical processes that occur at its surface can be exploited for highly efficient nanodevices. A facile and fast synthesis route has been explored that is free of catalysts or templates. An environmental scanning electron microscopy (ESEM) system was employed to grow titania nanowires (NWs) in a water vapor atmosphere (∼1 mbar) and to monitor the growth in situ. In addition, the growth process was also demonstrated using a simple vacuum chamber. In both processes, a titanium filament was heated via the Joule effect and NWs were found to grow on its surface, as a result of thermal oxidation processes. A variety of nanostructures were observed across the filament, with morphologies changing with the wire temperature from the center to the end points. The longest NWs were obtained for temperatures between ∼730 °C and 810 °C. Typically, they have an approximate thickness of ∼300 nm and lengths of up to a few micrometers. Cross sections prepared by focused-ion-beam milling revealed the presence of a porous layer beneath the NW clusters. This indicates that the growth of NWs is driven by oxidation-induced stresses in the subsurface region of the Ti filament and by enhanced diffusion along grain boundaries. To demonstrate the potential of titania NWs grown via the hot filament method, single NW devices were fabricated and used for conductometric sensing of hydrogen sulfide (H2S) gas. The NW electric resistance was found to decrease in the presence of H2S. Its variation can be explained in terms of the surface depletion model.

Original languageEnglish
Pages (from-to)1197-1205
Number of pages9
JournalACS Applied Materials and Interfaces
Volume5
Issue number4
DOIs
StatePublished - 27 Feb 2013
Externally publishedYes

Keywords

  • gas sensing
  • nanodevices
  • nanosensors
  • semiconductor nanostructures

ASJC Scopus subject areas

  • General Materials Science

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