Line-broadening effects in the powder infrared spectrum of apatite

The crystallinity of natural and synthetic apatite samples is often determined from the broadening of ν 4 PO 4 infrared absorption bands. However, various physical mechanisms contribute to the observed linewidth. In the present study, the factors determining the linewidth in the powder spectrum of s...

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Veröffentlicht in:	Phys Chem Minerals 2011-02, Vol.38 (2), p.111-122
Hauptverfasser:	Balan, Etienne, Delattre, Simon, Roche, Damien, Segalen, Loïc, Morin, Guillaume, Guillaumet, Maxime, Blanchard, Marc, Lazzeri, Michele, Brouder, Christian, Salje, Ekhard K. H.
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Schlagworte:	Absorption Absorption spectra Anharmonicity Apatite Biodiversity and Ecology Crystal structure Crystallinity Crystallography and Scattering Methods Density functional theory Dielectric properties Earth and Environmental Science Earth Sciences Electrical properties Environmental Sciences First principles Fluorapatite Geochemistry Hydroxyapatite Infrared absorption Line broadening Mineral Resources Mineralogy Original Paper Strain Temperature dependence
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container_title	Phys Chem Minerals
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description	The crystallinity of natural and synthetic apatite samples is often determined from the broadening of ν 4 PO 4 infrared absorption bands. However, various physical mechanisms contribute to the observed linewidth. In the present study, the factors determining the linewidth in the powder spectrum of synthetic fluorapatite and hydroxyapatite samples are investigated. The temperature dependence of the infrared spectrum (10–270 K) is used to assess the respective contributions of homogeneous broadening, related to the decay of phonons through anharmonic coupling, and heterogeneous broadening related to elastic strain and macroscopic electrostatic effects. This latter contribution is dominant in the investigated samples and depends on the shape of powder particles. It is discussed under the light of the theoretical modeling of the low-frequency dielectric properties of apatite based on first-principles density functional theory calculations. The linewidth of the weak ν 1 PO 4 absorption band provides a reliable information on microscopic sources of broadening, i.e., apatite crystallinity. In comparison, the other more intense PO 4 bands are more sensitive to long-range electrostatic effects.
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This latter contribution is dominant in the investigated samples and depends on the shape of powder particles. It is discussed under the light of the theoretical modeling of the low-frequency dielectric properties of apatite based on first-principles density functional theory calculations. The linewidth of the weak ν 1 PO 4 absorption band provides a reliable information on microscopic sources of broadening, i.e., apatite crystallinity. 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H.</creatorcontrib><title>Line-broadening effects in the powder infrared spectrum of apatite</title><title>Phys Chem Minerals</title><addtitle>Phys Chem Minerals</addtitle><description>The crystallinity of natural and synthetic apatite samples is often determined from the broadening of ν 4 PO 4 infrared absorption bands. However, various physical mechanisms contribute to the observed linewidth. In the present study, the factors determining the linewidth in the powder spectrum of synthetic fluorapatite and hydroxyapatite samples are investigated. The temperature dependence of the infrared spectrum (10–270 K) is used to assess the respective contributions of homogeneous broadening, related to the decay of phonons through anharmonic coupling, and heterogeneous broadening related to elastic strain and macroscopic electrostatic effects. This latter contribution is dominant in the investigated samples and depends on the shape of powder particles. It is discussed under the light of the theoretical modeling of the low-frequency dielectric properties of apatite based on first-principles density functional theory calculations. The linewidth of the weak ν 1 PO 4 absorption band provides a reliable information on microscopic sources of broadening, i.e., apatite crystallinity. 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subjects	Absorption Absorption spectra Anharmonicity Apatite Biodiversity and Ecology Crystal structure Crystallinity Crystallography and Scattering Methods Density functional theory Dielectric properties Earth and Environmental Science Earth Sciences Electrical properties Environmental Sciences First principles Fluorapatite Geochemistry Hydroxyapatite Infrared absorption Line broadening Mineral Resources Mineralogy Original Paper Strain Temperature dependence
title	Line-broadening effects in the powder infrared spectrum of apatite
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