Dielectric properties and polaronic conductivity of WO3 and W x Mo1−x O3

R. Gehlig; Ekhard K. H. Salje

doi:10.1080/13642812.1983.9728299

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JOURNAL ARTICLE

Dielectric properties and polaronic conductivity of WO₃ and W_xMo_1−xO₃

R. Gehlig Ekhard K. H. Salje

Year: 1983 Journal: Philosophical Magazine B Vol: 47 (3)Pages: 229-245 Publisher: Taylor & Francis

DOI: 10.1080/13642812.1983.9728299

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Abstract

Abstract An investigation of the Debye relaxations in WO3 and W x MO1−x O3 confirm the mechanism of polaronic conduction at low temperatures. The Mo positions act as trapping centres, and the relaxation times and activation energies depend largely on the crystallinity of the samples, Polarons are spin-paired in the ground state (bipolarons), and can be separated by optical irradiation giving rise to ‘inner’ photoconductivity. The transport mechanism of the bipolarons is found to take place in three steps : dissociation into two single polarons, their transport and subsequent recombination. This model is energetically favoured over the transport of the bipolarons as a whole.

Keywords:

Polaron Conductivity Trapping Photoconductivity Crystallinity Condensed matter physics Dielectric Relaxation (psychology) Materials science Thermal conduction Ground state Electron Electrical resistivity and conductivity Chemistry Atomic physics Physics Crystallography Physical chemistry Optoelectronics

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Transition Metal Oxide Nanomaterials

Physical Sciences → Materials Science → Polymers and Plastics

Glass properties and applications

Physical Sciences → Materials Science → Ceramics and Composites

Gas Sensing Nanomaterials and Sensors

Physical Sciences → Engineering → Electrical and Electronic Engineering

Dielectric properties and polaronic conductivity of WO₃ and W_xMo_1−xO₃

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