Nucleation pathways in barium silicate glasses

Matthew E. McKenzie; Binghui Deng; D. C. Van Hoesen; Xinsheng Xia; David E. Baker; Aram Rezikyan; Randall E. Youngman; K. F. Kelton

doi:10.1038/s41598-020-79749-2

Nucleation pathways in barium silicate glasses

Matthew E. McKenzie
, Binghui Deng
, D. C. Van Hoesen
, Xinsheng Xia
, David E. Baker
, Aram Rezikyan
, Randall E. Youngman
, K. F. Kelton

Department of Physics

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

17 Scopus citations

Abstract

Nucleation is generally viewed as a structural fluctuation that passes a critical size to eventually become a stable emerging new phase. However, this concept leaves out many details, such as changes in cluster composition and competing pathways to the new phase. In this work, both experimental and computer modeling studies are used to understand the cluster composition and pathways. Monte Carlo and molecular dynamics approaches are used to analyze the thermodynamic and kinetic contributions to the nucleation landscape in barium silicate glasses. Experimental techniques examine the resulting polycrystals that form. Both the modeling and experimental data indicate that a silica rich core plays a dominant role in the nucleation process.

Original language	English
Article number	69
Journal	Scientific reports
Volume	11
Issue number	1
DOIs	https://doi.org/10.1038/s41598-020-79749-2
State	Published - Dec 2021

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title = "Nucleation pathways in barium silicate glasses",

abstract = "Nucleation is generally viewed as a structural fluctuation that passes a critical size to eventually become a stable emerging new phase. However, this concept leaves out many details, such as changes in cluster composition and competing pathways to the new phase. In this work, both experimental and computer modeling studies are used to understand the cluster composition and pathways. Monte Carlo and molecular dynamics approaches are used to analyze the thermodynamic and kinetic contributions to the nucleation landscape in barium silicate glasses. Experimental techniques examine the resulting polycrystals that form. Both the modeling and experimental data indicate that a silica rich core plays a dominant role in the nucleation process.",

author = "McKenzie, \{Matthew E.\} and Binghui Deng and \{Van Hoesen\}, \{D. C.\} and Xinsheng Xia and Baker, \{David E.\} and Aram Rezikyan and Youngman, \{Randall E.\} and Kelton, \{K. F.\}",

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AU - Deng, Binghui

AU - Van Hoesen, D. C.

AU - Xia, Xinsheng

AU - Baker, David E.

AU - Rezikyan, Aram

AU - Youngman, Randall E.

AU - Kelton, K. F.

PY - 2021/12

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N2 - Nucleation is generally viewed as a structural fluctuation that passes a critical size to eventually become a stable emerging new phase. However, this concept leaves out many details, such as changes in cluster composition and competing pathways to the new phase. In this work, both experimental and computer modeling studies are used to understand the cluster composition and pathways. Monte Carlo and molecular dynamics approaches are used to analyze the thermodynamic and kinetic contributions to the nucleation landscape in barium silicate glasses. Experimental techniques examine the resulting polycrystals that form. Both the modeling and experimental data indicate that a silica rich core plays a dominant role in the nucleation process.

AB - Nucleation is generally viewed as a structural fluctuation that passes a critical size to eventually become a stable emerging new phase. However, this concept leaves out many details, such as changes in cluster composition and competing pathways to the new phase. In this work, both experimental and computer modeling studies are used to understand the cluster composition and pathways. Monte Carlo and molecular dynamics approaches are used to analyze the thermodynamic and kinetic contributions to the nucleation landscape in barium silicate glasses. Experimental techniques examine the resulting polycrystals that form. Both the modeling and experimental data indicate that a silica rich core plays a dominant role in the nucleation process.

UR - https://www.scopus.com/pages/publications/85098994962

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ER -

Nucleation pathways in barium silicate glasses

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