Mesoporous, mixed-valence tungsten oxides were synthesized by a straightforward, nonhydrolytic sol-gel method utilizing 1-butanol / tert-butanol mixtures as the gelling solvent. Composition of alcohol mixture has sensible effect on mesoporous characteristics of final product. By tuning synthesis and processing conditions specific surface area up to 140 m2/g was achieved with pore volume in excess of 0.5 cm3/g and fairly monodispersed pore-size around 18 nm. Presence of tungsten in WV-state besides WVI-state, as revealed by XPS, determines existence of oxygen vacancies in the structure. That confers important n-semiconducting characteristics upon these materials as demonstrated by EIS. Oxygen-vacancy concentration can effectively be varied by tuning conditions of thermal treatment, with strong impact on electrical properties. Electron conductivity of c.a. 20 S/cm was registered at room temperature for oxide subjected to treatment at 500°C. Upon wetting or humidification, these materials acquire also sensible proton-conduction characteristics. Proton conductivity in excess of 1.510–2 S/cm was measured at room temperature. As a result, these mesoporous oxides do exhibit concurrent electron and proton conduction properties under humidified conditions. Apparently, the porosity characteristics accompanied by mixed electron/proton conduction, make these materials especially appealing as conducting, mesoporous substrates utilizable in a variety of electrochemical systems, including fuel cells.
Facile nonhydrolytic sol–gel route to mesoporous mixed-conducting tungsten oxide
TRICOLI, VINCENZO
2011-01-01
Abstract
Mesoporous, mixed-valence tungsten oxides were synthesized by a straightforward, nonhydrolytic sol-gel method utilizing 1-butanol / tert-butanol mixtures as the gelling solvent. Composition of alcohol mixture has sensible effect on mesoporous characteristics of final product. By tuning synthesis and processing conditions specific surface area up to 140 m2/g was achieved with pore volume in excess of 0.5 cm3/g and fairly monodispersed pore-size around 18 nm. Presence of tungsten in WV-state besides WVI-state, as revealed by XPS, determines existence of oxygen vacancies in the structure. That confers important n-semiconducting characteristics upon these materials as demonstrated by EIS. Oxygen-vacancy concentration can effectively be varied by tuning conditions of thermal treatment, with strong impact on electrical properties. Electron conductivity of c.a. 20 S/cm was registered at room temperature for oxide subjected to treatment at 500°C. Upon wetting or humidification, these materials acquire also sensible proton-conduction characteristics. Proton conductivity in excess of 1.510–2 S/cm was measured at room temperature. As a result, these mesoporous oxides do exhibit concurrent electron and proton conduction properties under humidified conditions. Apparently, the porosity characteristics accompanied by mixed electron/proton conduction, make these materials especially appealing as conducting, mesoporous substrates utilizable in a variety of electrochemical systems, including fuel cells.File | Dimensione | Formato | |
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Descrizione: Supplementary Information for Straightforward Nonhydrolytic Sol-Gel Route to Mesoporous Mixed-Conducting Tungsten Oxide
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