Computational methods for the study of energies of cation distributions: Applications to cation-ordering phase transitions and solid solutions

A. Bosenick; M. T. Dove; E. R. Myers; E. J. Palin; C. I. Sainz-Diaz; B. S. Guiton; M. C. Warren; M. S. Craig; S. A.T. Redfern

doi:10.1180/002646101550226

Computational methods for the study of energies of cation distributions: Applications to cation-ordering phase transitions and solid solutions

A. Bosenick, M. T. Dove^*, E. R. Myers, E. J. Palin, C. I. Sainz-Diaz, B. S. Guiton, M. C. Warren, M. S. Craig, S. A.T. Redfern

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

80 Citations (Scopus)

Abstract

The structural and thermodynamic properties of minerals are strongly affected by cation site-ordering processes. We describe methods to determine the main interatomic interactions that drive the ordering process, which are based on parameterizing model Hamiltonians using empirical interatomic potentials and/or ab initio quantum mechanics methods. The methods are illustrated by a number of case study examples, including Al/Si ordering in aluminosilicates, Mg/Ca ordering in garnets, simultaneous Al/Si and Mg/Al ordering in pyroxenes, micas and amphiboles, and Mg/Al non-convergent ordering in spinel using only quantum mechanical methods.

Original language	English
Pages (from-to)	193-219
Number of pages	27
Journal	Mineralogical Magazine
Volume	65
Issue number	2
DOIs	https://doi.org/10.1180/002646101550226
Publication status	Published - Apr 2001
Externally published	Yes

ASJC Scopus Subject Areas

Geochemistry and Petrology

Keywords

Aluminosilicates
Cation ordering
Interatomic potentials
Monte Carlo simulation
Phase transitions

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10.1180/002646101550226

Cite this

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title = "Computational methods for the study of energies of cation distributions: Applications to cation-ordering phase transitions and solid solutions",

abstract = "The structural and thermodynamic properties of minerals are strongly affected by cation site-ordering processes. We describe methods to determine the main interatomic interactions that drive the ordering process, which are based on parameterizing model Hamiltonians using empirical interatomic potentials and/or ab initio quantum mechanics methods. The methods are illustrated by a number of case study examples, including Al/Si ordering in aluminosilicates, Mg/Ca ordering in garnets, simultaneous Al/Si and Mg/Al ordering in pyroxenes, micas and amphiboles, and Mg/Al non-convergent ordering in spinel using only quantum mechanical methods.",

keywords = "Aluminosilicates, Cation ordering, Interatomic potentials, Monte Carlo simulation, Phase transitions",

author = "A. Bosenick and Dove, {M. T.} and Myers, {E. R.} and Palin, {E. J.} and Sainz-Diaz, {C. I.} and Guiton, {B. S.} and Warren, {M. C.} and Craig, {M. S.} and Redfern, {S. A.T.}",

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language = "English",

volume = "65",

pages = "193--219",

journal = "Mineralogical Magazine",

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T1 - Computational methods for the study of energies of cation distributions

T2 - Applications to cation-ordering phase transitions and solid solutions

AU - Bosenick, A.

AU - Dove, M. T.

AU - Myers, E. R.

AU - Palin, E. J.

AU - Sainz-Diaz, C. I.

AU - Guiton, B. S.

AU - Warren, M. C.

AU - Craig, M. S.

AU - Redfern, S. A.T.

PY - 2001/4

Y1 - 2001/4

N2 - The structural and thermodynamic properties of minerals are strongly affected by cation site-ordering processes. We describe methods to determine the main interatomic interactions that drive the ordering process, which are based on parameterizing model Hamiltonians using empirical interatomic potentials and/or ab initio quantum mechanics methods. The methods are illustrated by a number of case study examples, including Al/Si ordering in aluminosilicates, Mg/Ca ordering in garnets, simultaneous Al/Si and Mg/Al ordering in pyroxenes, micas and amphiboles, and Mg/Al non-convergent ordering in spinel using only quantum mechanical methods.

AB - The structural and thermodynamic properties of minerals are strongly affected by cation site-ordering processes. We describe methods to determine the main interatomic interactions that drive the ordering process, which are based on parameterizing model Hamiltonians using empirical interatomic potentials and/or ab initio quantum mechanics methods. The methods are illustrated by a number of case study examples, including Al/Si ordering in aluminosilicates, Mg/Ca ordering in garnets, simultaneous Al/Si and Mg/Al ordering in pyroxenes, micas and amphiboles, and Mg/Al non-convergent ordering in spinel using only quantum mechanical methods.

KW - Aluminosilicates

KW - Cation ordering

KW - Interatomic potentials

KW - Monte Carlo simulation

KW - Phase transitions

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DO - 10.1180/002646101550226

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JO - Mineralogical Magazine

JF - Mineralogical Magazine

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Computational methods for the study of energies of cation distributions: Applications to cation-ordering phase transitions and solid solutions

Abstract

ASJC Scopus Subject Areas

Keywords

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