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Mechanism of Low‐Temperature Protonic Conductivity in Bulk, High‐Density, Nanometric Titanium Oxide
Author(s) -
Tredici Ilenia G.,
Maglia Filippo,
Ferrara Chiara,
Mustarelli Piercarlo,
AnselmiTamburini Umberto
Publication year - 2014
Publication title -
advanced functional materials
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 6.069
H-Index - 322
eISSN - 1616-3028
pISSN - 1616-301X
DOI - 10.1002/adfm.201400420
Subject(s) - materials science , conductivity , chemical physics , proton , oxide , ionization , electrolyte , thermal conduction , ceramic , chemical engineering , ion , chemistry , composite material , organic chemistry , electrode , physics , engineering , metallurgy , quantum mechanics
Uncovering the mechanism of low‐temperature protonic conduction in highly dense nanostructured metal oxides opens the possibility to exploit the application of simple ceramic electrolytes in proton exchange fuel cells, overcoming the drawbacks related to the use of polymeric membranes. High proton conducting, highly dense (relative density 94 vol%) TiO 2 samples are prepared by a fast pressure‐assisted sintering method, which allows leaving behind an interconnected network of open nanoporosity. Solid‐state 1 H NMR is used to characterize the presence of strongly associated water confined in the nanopores and hydroxyl moieties bonded to the pores walls, providing a model to explain the unusually high protonic conductivity. At the lowest temperatures ( T < 55 °C) protons hop between confined water molecules, according to a Grotthuss mechanism. The resulting conductivity values are however much higher than those of liquid water, indicating a significant increase in the charge carriers concentration. At higher temperatures (up to 450 °C) unexpected proton conduction is still present, thanks to the persistence of hydroxyl groups, derived from water chemisorption, which still produce protons by ionization. The phenomenon is strongly dependent on grain size, and not explicable by simple geometric brick‐layer models, suggesting that the enhanced ionization could rely on space charge region effects.

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