Transformation Pathways of Silica under High Pressure

AJ Gratz; BB Karki; D Andrault; DC Palmer; DD Klug; DM Teter; ECT Chao; EM Stolper; HT Stokes; J Badro; John Kieffer; JP Perdew; KJ Kingma; KJ Kingma; KJ Kingma; Liping Huang; LP Huang; LS Dubrovinsky; LW Hobbs; M O’Keeffe; M O’Keeffe; M Yamakata; Murat Durandurdu; N Binggeli; N Troullier; P Ordejón; R Hundt; RJ Hemley; RJ Hemley; RM Hazen; RM McMeeking; RM Wentzcovitch; S Tsuneyuki; T Demuth; VB Prokopenko; Y Tsuchida; Y Tsuchida; Y Yahagi

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Transformation Pathways of Silica under High Pressure

Authors: AJ Gratz
BB Karki
D Andrault
DC Palmer
DD Klug
DM Teter
ECT Chao
EM Stolper
HT Stokes
J Badro
John Kieffer
JP Perdew
KJ Kingma
KJ Kingma
KJ Kingma
Liping Huang
LP Huang
LS Dubrovinsky
LW Hobbs
M O’Keeffe
M O’Keeffe
M Yamakata
Murat Durandurdu
N Binggeli
N Troullier
P Ordejón
R Hundt
RJ Hemley
RJ Hemley
RM Hazen
RM McMeeking
RM Wentzcovitch
S Tsuneyuki
T Demuth
VB Prokopenko
Y Tsuchida
Y Tsuchida
Y Yahagi
Publication date: 11 February 2006
Publisher: 'Springer Science and Business Media LLC'
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Abstract

Concurrent molecular dynamics simulations and ab initio calculations show that densification of silica under pressure follows a ubiquitous two-stage mechanism. First, anions form a close-packed sub-lattice, governed by the strong repulsion between them. Next, cations redistribute onto the interstices. In cristobalite silica, the first stage is manifest by the formation of a metastable phase, which was observed experimentally a decade ago, but never indexed due to ambiguous diffraction patterns. Our simulations conclusively reveal its structure and its role in the densification of silica.Comment: 14 pages, 4 figure

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