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High-pressure, high temperature synthesis of a mesoporous α-quartz/bismuth nanowire composite

High temperature, high pressure conditions were used to insert liquid bismuth in 4–6 nm diameter amorphous silica nanotubes. A combination of transmission electron microscopy and neutron powder diffraction indicate that the final composite consists in 5–6 nm semi-conducting Bi nanowires confined in...

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Published in:	Solid state sciences 2020-03, Vol.101, p.106125, Article 106125
Main Authors:	Zhao, Yixuan, Talbi, Gaël, Clément, Sébastien, Toulemonde, Pierre, Hansen, Thomas, Cambon, Martine, Cambon, Olivier, Beaudhuin, Mickaël, Viennois, Romain, Haines, Julien
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Language:	English
Subjects:	Bismuth Chemical Sciences Guest insertion High pressure Material chemistry Nanocomposites Silica nanotubes
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container_title	Solid state sciences
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creator	Zhao, Yixuan Talbi, Gaël Clément, Sébastien Toulemonde, Pierre Hansen, Thomas Cambon, Martine Cambon, Olivier Beaudhuin, Mickaël Viennois, Romain Haines, Julien
description	High temperature, high pressure conditions were used to insert liquid bismuth in 4–6 nm diameter amorphous silica nanotubes. A combination of transmission electron microscopy and neutron powder diffraction indicate that the final composite consists in 5–6 nm semi-conducting Bi nanowires confined in insulating mesoporous α-quartz. Such a nanostructured material could be of considerable interest for thermoelectric applications. [Display omitted] •Bismuth was inserted into 4–6 nm silica nanotubes under high-pressure, high-temperature conditions.•The host amorphous nanotubes crystallize in the form of α-quartz.•The obtained nanocomposite consists of 5–6 nm Bi nanowires imbedded in mesoporous α-quartz.•The formation of Bi nanowires modifies their physical properties compared to bulk Bi.
doi_str_mv	10.1016/j.solidstatesciences.2020.106125
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subjects	Bismuth Chemical Sciences Guest insertion High pressure Material chemistry Nanocomposites Silica nanotubes
title	High-pressure, high temperature synthesis of a mesoporous α-quartz/bismuth nanowire composite
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