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A mechanism for the sphere/tube shape transition of nanoparticles with an imogolite local structure (imogolite and allophane)

Imogolite and allophane are two strongly curved nanominerals. Indeed, imogolite has a tubular shape with a diameter of only 2.5nm. Allophane is often presented as a spherical nanostructure with a diameter of about 5nm. The mechanism explaining the strong curvature of these two nanominerals has been...

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Published in:Applied clay science 2017-06, Vol.141, p.308-315
Main Authors: Thill, A., Picot, P., Belloni, L.
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Language:English
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description Imogolite and allophane are two strongly curved nanominerals. Indeed, imogolite has a tubular shape with a diameter of only 2.5nm. Allophane is often presented as a spherical nanostructure with a diameter of about 5nm. The mechanism explaining the strong curvature of these two nanominerals has been extensively discussed. However, whether or not these two nanomaterials are related to each other is not clear and the mechanism responsible for the selection between the two different shapes is not well established. In this article, we propose that imogolite and allophane are nanopolymorphs of the imogolite local structure and that the transition from spherical to tubular shape occurs at an early stage of the precipitation because of edge stress in proto-imogolite. This hypothesis for the shape selection is supported by the use of a nanomechanical model tuned to mimic the main characteristics of imogolite-like nanomaterials. [Display omitted] •Imogolite and allophane are polymorphs of the imogolite local structure.•The curvature of imogolite is due to AlO/SiO bond distances and hydrogen bonds.•The imogolite structure is oriented.•Above a size threshold a transition from spherical and tubular shape occurs.•The initial sizes of proto-imogolite control the proportion of imogolite and allophane.
doi_str_mv 10.1016/j.clay.2017.03.011
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source ScienceDirect Journals
subjects Allophane
Chemical Sciences
Crystal polymorph
Imogolite
Material chemistry
Molecular dynamic
title A mechanism for the sphere/tube shape transition of nanoparticles with an imogolite local structure (imogolite and allophane)
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