An ab initio study of the structure and properties of aluminum hydroxide: Gibbsite and bayerite

Julian D. Gale; Andrew L. Rohl; Victor Milman; Michele C. Warren

doi:10.1021/jp011795e

An ab initio study of the structure and properties of aluminum hydroxide: Gibbsite and bayerite

Julian D. Gale, Andrew L. Rohl, Victor Milman, Michele C. Warren

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Abstract

The two most important polymorphs of aluminum hydroxide, namely gibbsite and bayerite, have been studied for the first time using solid state ab initio quantum mechanical methods, both using plane wave and localized basis set methodologies, within the framework of nonlocal density functional theory. The fully optimized structures have been determined for both phases, yielding improved hydrogen positions in the case of gibbsite for which the only previous information is from X-ray data. Mechanical properties have been calculated for gibbsite, including the full elastic constants tensor and the bulk modulus. The latter is found to be 55 GPa, which is significantly lower than a recent experimental estimate. Vibrational spectra have been calculated for both phases and assignments of the hydroxyl stretching modes are proposed.

Original language	English
Pages (from-to)	10236-10242
Number of pages	6
Journal	Journal of Physical Chemistry B
Volume	105
Issue number	42
DOIs	https://doi.org/10.1021/jp011795e
Publication status	Published - 25 Oct 2001

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title = "An ab initio study of the structure and properties of aluminum hydroxide: Gibbsite and bayerite",

abstract = "The two most important polymorphs of aluminum hydroxide, namely gibbsite and bayerite, have been studied for the first time using solid state ab initio quantum mechanical methods, both using plane wave and localized basis set methodologies, within the framework of nonlocal density functional theory. The fully optimized structures have been determined for both phases, yielding improved hydrogen positions in the case of gibbsite for which the only previous information is from X-ray data. Mechanical properties have been calculated for gibbsite, including the full elastic constants tensor and the bulk modulus. The latter is found to be 55 GPa, which is significantly lower than a recent experimental estimate. Vibrational spectra have been calculated for both phases and assignments of the hydroxyl stretching modes are proposed.",

author = "Gale, {Julian D.} and Rohl, {Andrew L.} and Victor Milman and Warren, {Michele C.}",

year = "2001",

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journal = "Journal of Physical Chemistry B",

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TY - JOUR

T1 - An ab initio study of the structure and properties of aluminum hydroxide: Gibbsite and bayerite

AU - Gale, Julian D.

AU - Rohl, Andrew L.

AU - Milman, Victor

AU - Warren, Michele C.

PY - 2001/10/25

Y1 - 2001/10/25

N2 - The two most important polymorphs of aluminum hydroxide, namely gibbsite and bayerite, have been studied for the first time using solid state ab initio quantum mechanical methods, both using plane wave and localized basis set methodologies, within the framework of nonlocal density functional theory. The fully optimized structures have been determined for both phases, yielding improved hydrogen positions in the case of gibbsite for which the only previous information is from X-ray data. Mechanical properties have been calculated for gibbsite, including the full elastic constants tensor and the bulk modulus. The latter is found to be 55 GPa, which is significantly lower than a recent experimental estimate. Vibrational spectra have been calculated for both phases and assignments of the hydroxyl stretching modes are proposed.

AB - The two most important polymorphs of aluminum hydroxide, namely gibbsite and bayerite, have been studied for the first time using solid state ab initio quantum mechanical methods, both using plane wave and localized basis set methodologies, within the framework of nonlocal density functional theory. The fully optimized structures have been determined for both phases, yielding improved hydrogen positions in the case of gibbsite for which the only previous information is from X-ray data. Mechanical properties have been calculated for gibbsite, including the full elastic constants tensor and the bulk modulus. The latter is found to be 55 GPa, which is significantly lower than a recent experimental estimate. Vibrational spectra have been calculated for both phases and assignments of the hydroxyl stretching modes are proposed.

U2 - 10.1021/jp011795e

DO - 10.1021/jp011795e

M3 - Article

SN - 1520-6106

VL - 105

SP - 10236

EP - 10242

JO - Journal of Physical Chemistry B

JF - Journal of Physical Chemistry B

IS - 42

ER -

An ab initio study of the structure and properties of aluminum hydroxide: Gibbsite and bayerite

Abstract

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