Observation of the role of subcritical nuclei in crystallization of a glassy solid

Bong Sub Lee; Geoffrey W. Burr; Robert M. Shelby; Simone Raoux; Charles T. Rettner; Stephanie N. Bogle; Kristof Darmawikarta; Stephen G. Bishop; John R. Abelson

doi:10.1126/science.1177483

Observation of the role of subcritical nuclei in crystallization of a glassy solid

Bong Sub Lee, Geoffrey W. Burr, Robert M. Shelby, Simone Raoux, Charles T. Rettner, Stephanie N. Bogle, Kristof Darmawikarta, Stephen G. Bishop, John R. Abelson

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

Abstract

Phase transformation generally begins with nucleation, in which a small aggregate of atoms organizes into a different structural symmetry. The thermodynamic driving forces and kinetic rates have been predicted by classical nucleation theory, but observation of nanometer-scale nuclei has not been possible, except on exposed surfaces. We used a statistical technique called fluctuation transmission electron microscopy to detect nuclei embedded in a glassy solid, and we used a laser pump-probe technique to determine the role of these nuclei in crystallization. This study provides a convincing proof of the time- and temperature-dependent development of nuclei, information that will play a critical role in the development of advanced materials for phase-change memories.

Original language	English (US)
Pages (from-to)	980-984
Number of pages	5
Journal	Science
Volume	326
Issue number	5955
DOIs	https://doi.org/10.1126/science.1177483
State	Published - Nov 13 2009

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title = "Observation of the role of subcritical nuclei in crystallization of a glassy solid",

abstract = "Phase transformation generally begins with nucleation, in which a small aggregate of atoms organizes into a different structural symmetry. The thermodynamic driving forces and kinetic rates have been predicted by classical nucleation theory, but observation of nanometer-scale nuclei has not been possible, except on exposed surfaces. We used a statistical technique called fluctuation transmission electron microscopy to detect nuclei embedded in a glassy solid, and we used a laser pump-probe technique to determine the role of these nuclei in crystallization. This study provides a convincing proof of the time- and temperature-dependent development of nuclei, information that will play a critical role in the development of advanced materials for phase-change memories.",

author = "Lee, {Bong Sub} and Burr, {Geoffrey W.} and Shelby, {Robert M.} and Simone Raoux and Rettner, {Charles T.} and Bogle, {Stephanie N.} and Kristof Darmawikarta and Bishop, {Stephen G.} and Abelson, {John R.}",

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AU - Lee, Bong Sub

AU - Burr, Geoffrey W.

AU - Shelby, Robert M.

AU - Raoux, Simone

AU - Rettner, Charles T.

AU - Bogle, Stephanie N.

AU - Darmawikarta, Kristof

AU - Bishop, Stephen G.

AU - Abelson, John R.

PY - 2009/11/13

Y1 - 2009/11/13

N2 - Phase transformation generally begins with nucleation, in which a small aggregate of atoms organizes into a different structural symmetry. The thermodynamic driving forces and kinetic rates have been predicted by classical nucleation theory, but observation of nanometer-scale nuclei has not been possible, except on exposed surfaces. We used a statistical technique called fluctuation transmission electron microscopy to detect nuclei embedded in a glassy solid, and we used a laser pump-probe technique to determine the role of these nuclei in crystallization. This study provides a convincing proof of the time- and temperature-dependent development of nuclei, information that will play a critical role in the development of advanced materials for phase-change memories.

AB - Phase transformation generally begins with nucleation, in which a small aggregate of atoms organizes into a different structural symmetry. The thermodynamic driving forces and kinetic rates have been predicted by classical nucleation theory, but observation of nanometer-scale nuclei has not been possible, except on exposed surfaces. We used a statistical technique called fluctuation transmission electron microscopy to detect nuclei embedded in a glassy solid, and we used a laser pump-probe technique to determine the role of these nuclei in crystallization. This study provides a convincing proof of the time- and temperature-dependent development of nuclei, information that will play a critical role in the development of advanced materials for phase-change memories.

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Observation of the role of subcritical nuclei in crystallization of a glassy solid

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