Virtual probes of mineral-water interfaces: The more flops, the better!

Andrew G. Stack; Julian D. Gale; Paolo Raiteri

doi:10.2113/gselements.9.3.211

Virtual probes of mineral-water interfaces: The more flops, the better!

Andrew G. Stack
, Julian D. Gale
, Paolo Raiteri

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

16 Scopus citations

Abstract

New approaches are allowing computer simulations to be compared quantitatively with experimental results, and they are also raising new questions about reactivity at mineral-water interfaces. Molecular simulations not only help us to understand experimental observations, they can also be used to test hypotheses about the properties of geochemical systems. These new approaches include rigorous calibration of simulation models against thermodynamic properties and atomic structure. They also encompass rare event theory methods that allow simulation of slow, complex mineral surface reactions. Here, we give an overview of how these techniques have been applied to simulate mineral-water interface structure, growth/ dissolution mechanisms, and cluster formation.

Original language	English
Pages (from-to)	211-216
Number of pages	6
Journal	Elements
Volume	9
Issue number	3
DOIs	https://doi.org/10.2113/gselements.9.3.211
State	Published - Jun 2013

Keywords

Barite
Calcite
Kinetics
Molecular dynamics
Simulation

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10.2113/gselements.9.3.211

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title = "Virtual probes of mineral-water interfaces: The more flops, the better!",

abstract = "New approaches are allowing computer simulations to be compared quantitatively with experimental results, and they are also raising new questions about reactivity at mineral-water interfaces. Molecular simulations not only help us to understand experimental observations, they can also be used to test hypotheses about the properties of geochemical systems. These new approaches include rigorous calibration of simulation models against thermodynamic properties and atomic structure. They also encompass rare event theory methods that allow simulation of slow, complex mineral surface reactions. Here, we give an overview of how these techniques have been applied to simulate mineral-water interface structure, growth/ dissolution mechanisms, and cluster formation.",

keywords = "Barite, Calcite, Kinetics, Molecular dynamics, Simulation",

author = "Stack, \{Andrew G.\} and Gale, \{Julian D.\} and Paolo Raiteri",

year = "2013",

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doi = "10.2113/gselements.9.3.211",

language = "English",

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AU - Stack, Andrew G.

AU - Gale, Julian D.

AU - Raiteri, Paolo

PY - 2013/6

Y1 - 2013/6

N2 - New approaches are allowing computer simulations to be compared quantitatively with experimental results, and they are also raising new questions about reactivity at mineral-water interfaces. Molecular simulations not only help us to understand experimental observations, they can also be used to test hypotheses about the properties of geochemical systems. These new approaches include rigorous calibration of simulation models against thermodynamic properties and atomic structure. They also encompass rare event theory methods that allow simulation of slow, complex mineral surface reactions. Here, we give an overview of how these techniques have been applied to simulate mineral-water interface structure, growth/ dissolution mechanisms, and cluster formation.

AB - New approaches are allowing computer simulations to be compared quantitatively with experimental results, and they are also raising new questions about reactivity at mineral-water interfaces. Molecular simulations not only help us to understand experimental observations, they can also be used to test hypotheses about the properties of geochemical systems. These new approaches include rigorous calibration of simulation models against thermodynamic properties and atomic structure. They also encompass rare event theory methods that allow simulation of slow, complex mineral surface reactions. Here, we give an overview of how these techniques have been applied to simulate mineral-water interface structure, growth/ dissolution mechanisms, and cluster formation.

KW - Barite

KW - Calcite

KW - Kinetics

KW - Molecular dynamics

KW - Simulation

UR - https://www.scopus.com/pages/publications/84880157786

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VL - 9

SP - 211

EP - 216

JO - Elements

JF - Elements

IS - 3

ER -

Virtual probes of mineral-water interfaces: The more flops, the better!

Abstract

Keywords

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