Topological Control of Water Reactivity on Glass Surfaces: Evidence of a Chemically Stable Intermediate Phase

Collin J. Wilkinson; Karan Doss; Seung Ho Hahn; Nathan Keilbart; Arron R. Potter; Nicholas J. Smith; Ismaila Dabo; Adri C.T. Van Duin; Seong H. Kim; John C. Mauro

doi:10.1021/acs.jpclett.9b01275

Topological Control of Water Reactivity on Glass Surfaces: Evidence of a Chemically Stable Intermediate Phase

Collin J. Wilkinson, Karan Doss, Seung Ho Hahn, Nathan Keilbart, Arron R. Potter, Nicholas J. Smith, Ismaila Dabo, Adri C.T. Van Duin, Seong H. Kim, John C. Mauro

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

7 Scopus citations

Abstract

Glass surfaces are of considerable interest due to their disproportionately large influence on the performance of glass articles in many applications. However, the behavior of glass surfaces has proven difficult to model and predict due to their complex structure and interactions with the environment. Here, the effects of glass network topology on the surface reactivity of glasses have been investigated using reactive and nonreactive force field-based molecular dynamics simulations as well as density functional theory. A topological constraint-based description for surface reactivity is developed, allowing for improved understanding of the physical and chemical origins of surface reactivity. Results show evidence for the existence of a chemically stable intermediate phase on the surface of the glass where the glass network is mechanically isostatic.

Original language	English (US)
Pages (from-to)	3955-3960
Number of pages	6
Journal	Journal of Physical Chemistry Letters
Volume	10
Issue number	14
DOIs	https://doi.org/10.1021/acs.jpclett.9b01275
State	Published - Jun 26 2019

All Science Journal Classification (ASJC) codes

General Materials Science
Physical and Theoretical Chemistry

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10.1021/acs.jpclett.9b01275

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title = "Topological Control of Water Reactivity on Glass Surfaces: Evidence of a Chemically Stable Intermediate Phase",

abstract = "Glass surfaces are of considerable interest due to their disproportionately large influence on the performance of glass articles in many applications. However, the behavior of glass surfaces has proven difficult to model and predict due to their complex structure and interactions with the environment. Here, the effects of glass network topology on the surface reactivity of glasses have been investigated using reactive and nonreactive force field-based molecular dynamics simulations as well as density functional theory. A topological constraint-based description for surface reactivity is developed, allowing for improved understanding of the physical and chemical origins of surface reactivity. Results show evidence for the existence of a chemically stable intermediate phase on the surface of the glass where the glass network is mechanically isostatic.",

author = "Wilkinson, {Collin J.} and Karan Doss and Hahn, {Seung Ho} and Nathan Keilbart and Potter, {Arron R.} and Smith, {Nicholas J.} and Ismaila Dabo and {Van Duin}, {Adri C.T.} and Kim, {Seong H.} and Mauro, {John C.}",

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AU - Wilkinson, Collin J.

AU - Doss, Karan

AU - Hahn, Seung Ho

AU - Keilbart, Nathan

AU - Potter, Arron R.

AU - Smith, Nicholas J.

AU - Dabo, Ismaila

AU - Van Duin, Adri C.T.

AU - Kim, Seong H.

AU - Mauro, John C.

PY - 2019/6/26

Y1 - 2019/6/26

N2 - Glass surfaces are of considerable interest due to their disproportionately large influence on the performance of glass articles in many applications. However, the behavior of glass surfaces has proven difficult to model and predict due to their complex structure and interactions with the environment. Here, the effects of glass network topology on the surface reactivity of glasses have been investigated using reactive and nonreactive force field-based molecular dynamics simulations as well as density functional theory. A topological constraint-based description for surface reactivity is developed, allowing for improved understanding of the physical and chemical origins of surface reactivity. Results show evidence for the existence of a chemically stable intermediate phase on the surface of the glass where the glass network is mechanically isostatic.

AB - Glass surfaces are of considerable interest due to their disproportionately large influence on the performance of glass articles in many applications. However, the behavior of glass surfaces has proven difficult to model and predict due to their complex structure and interactions with the environment. Here, the effects of glass network topology on the surface reactivity of glasses have been investigated using reactive and nonreactive force field-based molecular dynamics simulations as well as density functional theory. A topological constraint-based description for surface reactivity is developed, allowing for improved understanding of the physical and chemical origins of surface reactivity. Results show evidence for the existence of a chemically stable intermediate phase on the surface of the glass where the glass network is mechanically isostatic.

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Topological Control of Water Reactivity on Glass Surfaces: Evidence of a Chemically Stable Intermediate Phase

Abstract

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