Structural crossover in a supercooled metallic liquid and the link to a liquid-to-liquid phase transition

S. Lan; M. Blodgett; K. F. Kelton; J. L. Ma; J. Fan; X. L. Wang

doi:10.1063/1.4952724

Structural crossover in a supercooled metallic liquid and the link to a liquid-to-liquid phase transition

S. Lan
, M. Blodgett
, K. F. Kelton
, J. L. Ma
, J. Fan
, X. L. Wang

Department of Physics

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

70 Scopus citations

Abstract

Time-resolved synchrotron measurements were carried out to capture the structure evolution of an electrostatically levitated metallic-glass-forming liquid during free cooling. The experimental data shows a crossover in the liquid structure at ∼1000 K, about 115 K below the melting temperature and 150 K above the crystallization temperature. The structure change is characterized by a dramatic growth in the extended-range order below the crossover temperature. Molecular dynamics simulations have identified that the growth of the extended-range order was due to an increased correlation between solute atoms. These results provide structural evidence for a liquid-to-liquid-phase-transition in the supercooled metallic liquid.

Original language	English
Article number	211907
Journal	Applied Physics Letters
Volume	108
Issue number	21
DOIs	https://doi.org/10.1063/1.4952724
State	Published - May 23 2016

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title = "Structural crossover in a supercooled metallic liquid and the link to a liquid-to-liquid phase transition",

abstract = "Time-resolved synchrotron measurements were carried out to capture the structure evolution of an electrostatically levitated metallic-glass-forming liquid during free cooling. The experimental data shows a crossover in the liquid structure at ∼1000 K, about 115 K below the melting temperature and 150 K above the crystallization temperature. The structure change is characterized by a dramatic growth in the extended-range order below the crossover temperature. Molecular dynamics simulations have identified that the growth of the extended-range order was due to an increased correlation between solute atoms. These results provide structural evidence for a liquid-to-liquid-phase-transition in the supercooled metallic liquid.",

author = "S. Lan and M. Blodgett and Kelton, \{K. F.\} and Ma, \{J. L.\} and J. Fan and Wang, \{X. L.\}",

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T1 - Structural crossover in a supercooled metallic liquid and the link to a liquid-to-liquid phase transition

AU - Lan, S.

AU - Blodgett, M.

AU - Kelton, K. F.

AU - Ma, J. L.

AU - Fan, J.

AU - Wang, X. L.

PY - 2016/5/23

Y1 - 2016/5/23

N2 - Time-resolved synchrotron measurements were carried out to capture the structure evolution of an electrostatically levitated metallic-glass-forming liquid during free cooling. The experimental data shows a crossover in the liquid structure at ∼1000 K, about 115 K below the melting temperature and 150 K above the crystallization temperature. The structure change is characterized by a dramatic growth in the extended-range order below the crossover temperature. Molecular dynamics simulations have identified that the growth of the extended-range order was due to an increased correlation between solute atoms. These results provide structural evidence for a liquid-to-liquid-phase-transition in the supercooled metallic liquid.

AB - Time-resolved synchrotron measurements were carried out to capture the structure evolution of an electrostatically levitated metallic-glass-forming liquid during free cooling. The experimental data shows a crossover in the liquid structure at ∼1000 K, about 115 K below the melting temperature and 150 K above the crystallization temperature. The structure change is characterized by a dramatic growth in the extended-range order below the crossover temperature. Molecular dynamics simulations have identified that the growth of the extended-range order was due to an increased correlation between solute atoms. These results provide structural evidence for a liquid-to-liquid-phase-transition in the supercooled metallic liquid.

UR - https://www.scopus.com/pages/publications/84971554695

U2 - 10.1063/1.4952724

DO - 10.1063/1.4952724

M3 - Article

AN - SCOPUS:84971554695

SN - 0003-6951

VL - 108

JO - Applied Physics Letters

JF - Applied Physics Letters

IS - 21

M1 - 211907

ER -

Structural crossover in a supercooled metallic liquid and the link to a liquid-to-liquid phase transition

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