Dissociative melting of ice VII at high pressure

Alexander F. Goncharov; Chrystele Sanloup; Nir Goldman; Jonathan C. Crowhurst; Sorin Bastea; W. M. Howard; Laurence E. Fried; Nicolas Guignot; Mohamed Mezouar; Yue Meng

doi:10.1063/1.3100771

Dissociative melting of ice VII at high pressure

Alexander F. Goncharov, Chrystele Sanloup, Nir Goldman, Jonathan C. Crowhurst, Sorin Bastea, W. M. Howard, Laurence E. Fried, Nicolas Guignot, Mohamed Mezouar, Yue Meng

School of Physics and Astronomy

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

Abstract

We have used x-ray diffraction to determine the structure factor of water along its melting line to a static pressure of 57 GPa (570 kbar) and a temperature of more than 1500 K, conditions which correspond to the lower mantle of the Earth, and the interiors of Neptune and Uranus up to a depth of 7000 km. We have also performed corresponding first principles and classical molecular dynamics simulations. Above a pressure of 4 GPa the O-O structure factor is found to be very close to that of a simple soft sphere liquid, thus permitting us to determine the density of liquid water near the melting line. By comparing these results with the density of ice, also determined in this study, we find that the enthalpy of fusion (Delta H-f) increases enormously along the melting line, reaching approximately 120 kJ/mole at 40 GPa (compared to 6 kJ/mole at 0 GPa), thus revealing significant molecular dissociation of water upon melting. We speculate that an extended two-phase region could occur in planetary processes involving the adiabatic compression of water.

Original language	English
Article number	124514
Pages (from-to)	-
Number of pages	9
Journal	The Journal of Chemical Physics
Volume	130
Issue number	12
DOIs	https://doi.org/10.1063/1.3100771
Publication status	Published - 28 Mar 2009

Keywords / Materials (for Non-textual outputs)

ab initio calculations
compressibility
crystal structure
density
dissociation
Earth mantle
enthalpy
geochemistry
heat of fusion
high-pressure effects
ice
melting
molecular dynamics method
Neptune
planetary interiors
Uranus
X-ray diffraction
X-RAY-DIFFRACTION
DENSITY-FUNCTIONAL THEORY
EQUATION-OF-STATE
LIQUID WATER
ELECTRICAL-CONDUCTIVITY
MOLECULAR-DYNAMICS
1ST PRINCIPLES
H2O
TEMPERATURE
INTENSITIES

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10.1063/1.3100771

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title = "Dissociative melting of ice VII at high pressure",

abstract = "We have used x-ray diffraction to determine the structure factor of water along its melting line to a static pressure of 57 GPa (570 kbar) and a temperature of more than 1500 K, conditions which correspond to the lower mantle of the Earth, and the interiors of Neptune and Uranus up to a depth of 7000 km. We have also performed corresponding first principles and classical molecular dynamics simulations. Above a pressure of 4 GPa the O-O structure factor is found to be very close to that of a simple soft sphere liquid, thus permitting us to determine the density of liquid water near the melting line. By comparing these results with the density of ice, also determined in this study, we find that the enthalpy of fusion (Delta H-f) increases enormously along the melting line, reaching approximately 120 kJ/mole at 40 GPa (compared to 6 kJ/mole at 0 GPa), thus revealing significant molecular dissociation of water upon melting. We speculate that an extended two-phase region could occur in planetary processes involving the adiabatic compression of water.",

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author = "Goncharov, {Alexander F.} and Chrystele Sanloup and Nir Goldman and Crowhurst, {Jonathan C.} and Sorin Bastea and Howard, {W. M.} and Fried, {Laurence E.} and Nicolas Guignot and Mohamed Mezouar and Yue Meng",

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doi = "10.1063/1.3100771",

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T1 - Dissociative melting of ice VII at high pressure

AU - Goncharov, Alexander F.

AU - Sanloup, Chrystele

AU - Goldman, Nir

AU - Crowhurst, Jonathan C.

AU - Bastea, Sorin

AU - Howard, W. M.

AU - Fried, Laurence E.

AU - Guignot, Nicolas

AU - Mezouar, Mohamed

AU - Meng, Yue

PY - 2009/3/28

Y1 - 2009/3/28

N2 - We have used x-ray diffraction to determine the structure factor of water along its melting line to a static pressure of 57 GPa (570 kbar) and a temperature of more than 1500 K, conditions which correspond to the lower mantle of the Earth, and the interiors of Neptune and Uranus up to a depth of 7000 km. We have also performed corresponding first principles and classical molecular dynamics simulations. Above a pressure of 4 GPa the O-O structure factor is found to be very close to that of a simple soft sphere liquid, thus permitting us to determine the density of liquid water near the melting line. By comparing these results with the density of ice, also determined in this study, we find that the enthalpy of fusion (Delta H-f) increases enormously along the melting line, reaching approximately 120 kJ/mole at 40 GPa (compared to 6 kJ/mole at 0 GPa), thus revealing significant molecular dissociation of water upon melting. We speculate that an extended two-phase region could occur in planetary processes involving the adiabatic compression of water.

AB - We have used x-ray diffraction to determine the structure factor of water along its melting line to a static pressure of 57 GPa (570 kbar) and a temperature of more than 1500 K, conditions which correspond to the lower mantle of the Earth, and the interiors of Neptune and Uranus up to a depth of 7000 km. We have also performed corresponding first principles and classical molecular dynamics simulations. Above a pressure of 4 GPa the O-O structure factor is found to be very close to that of a simple soft sphere liquid, thus permitting us to determine the density of liquid water near the melting line. By comparing these results with the density of ice, also determined in this study, we find that the enthalpy of fusion (Delta H-f) increases enormously along the melting line, reaching approximately 120 kJ/mole at 40 GPa (compared to 6 kJ/mole at 0 GPa), thus revealing significant molecular dissociation of water upon melting. We speculate that an extended two-phase region could occur in planetary processes involving the adiabatic compression of water.

KW - ab initio calculations

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KW - crystal structure

KW - density

KW - dissociation

KW - Earth mantle

KW - enthalpy

KW - geochemistry

KW - heat of fusion

KW - high-pressure effects

KW - ice

KW - melting

KW - molecular dynamics method

KW - Neptune

KW - planetary interiors

KW - Uranus

KW - X-ray diffraction

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KW - DENSITY-FUNCTIONAL THEORY

KW - EQUATION-OF-STATE

KW - LIQUID WATER

KW - ELECTRICAL-CONDUCTIVITY

KW - MOLECULAR-DYNAMICS

KW - 1ST PRINCIPLES

KW - H2O

KW - TEMPERATURE

KW - INTENSITIES

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DO - 10.1063/1.3100771

M3 - Article

SN - 0021-9606

VL - 130

SP - -

JO - The Journal of Chemical Physics

JF - The Journal of Chemical Physics

IS - 12

M1 - 124514

ER -

Dissociative melting of ice VII at high pressure

Abstract

Keywords / Materials (for Non-textual outputs)

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