Ultrafast growth kinetics of titanium dendrites investigated by electrostatic levitation experiments and molecular dynamics simulations

L. Wang; L. Hu; J. F. Zhao; B. Wei

doi:10.1016/j.cplett.2020.137141

Ultrafast growth kinetics of titanium dendrites investigated by electrostatic levitation experiments and molecular dynamics simulations

L. Wang, L. Hu, J. F. Zhao, B. Wei

物理科学与技术学院

Northwestern Polytechnical University Xian

科研成果: 期刊稿件 › 文章 › 同行评审

8 引用（Scopus）

摘要

An ultrafast crystal growth velocity of 122 m/s for β–Ti dendrites was achieved at a liquid undercooling of 352 K (0.18T_m) by electrostatic levitation technique. In contrast, most refractory metals attained slower dendrite growth velocities but displayed similar power laws with liquid undercooling. A combined analysis by current dendrite growth theory with molecular dynamics simulation indicates that liquid thermal diffusion rather than solid-liquid (S/L) interface kinetics is still the dominant factor to control dendrite growth. Besides, the atomic-scale thickness of the S/L interface layer may determine the dendrite growth velocity difference for various refractory metals.

源语言	英语
文章编号	137141
期刊	Chemical Physics Letters
卷	742
DOI	https://doi.org/10.1016/j.cplett.2020.137141
出版状态	已出版 - 3月 2020

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title = "Ultrafast growth kinetics of titanium dendrites investigated by electrostatic levitation experiments and molecular dynamics simulations",

abstract = "An ultrafast crystal growth velocity of 122 m/s for β–Ti dendrites was achieved at a liquid undercooling of 352 K (0.18Tm) by electrostatic levitation technique. In contrast, most refractory metals attained slower dendrite growth velocities but displayed similar power laws with liquid undercooling. A combined analysis by current dendrite growth theory with molecular dynamics simulation indicates that liquid thermal diffusion rather than solid-liquid (S/L) interface kinetics is still the dominant factor to control dendrite growth. Besides, the atomic-scale thickness of the S/L interface layer may determine the dendrite growth velocity difference for various refractory metals.",

keywords = "Molecular dynamics, Rapid dendritic growth, Refractory metals, Undercooling",

author = "L. Wang and L. Hu and Zhao, {J. F.} and B. Wei",

note = "Publisher Copyright: {\textcopyright} 2020 Elsevier B.V.",

year = "2020",

month = mar,

doi = "10.1016/j.cplett.2020.137141",

language = "英语",

volume = "742",

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T1 - Ultrafast growth kinetics of titanium dendrites investigated by electrostatic levitation experiments and molecular dynamics simulations

AU - Wang, L.

AU - Hu, L.

AU - Zhao, J. F.

AU - Wei, B.

PY - 2020/3

Y1 - 2020/3

N2 - An ultrafast crystal growth velocity of 122 m/s for β–Ti dendrites was achieved at a liquid undercooling of 352 K (0.18Tm) by electrostatic levitation technique. In contrast, most refractory metals attained slower dendrite growth velocities but displayed similar power laws with liquid undercooling. A combined analysis by current dendrite growth theory with molecular dynamics simulation indicates that liquid thermal diffusion rather than solid-liquid (S/L) interface kinetics is still the dominant factor to control dendrite growth. Besides, the atomic-scale thickness of the S/L interface layer may determine the dendrite growth velocity difference for various refractory metals.

AB - An ultrafast crystal growth velocity of 122 m/s for β–Ti dendrites was achieved at a liquid undercooling of 352 K (0.18Tm) by electrostatic levitation technique. In contrast, most refractory metals attained slower dendrite growth velocities but displayed similar power laws with liquid undercooling. A combined analysis by current dendrite growth theory with molecular dynamics simulation indicates that liquid thermal diffusion rather than solid-liquid (S/L) interface kinetics is still the dominant factor to control dendrite growth. Besides, the atomic-scale thickness of the S/L interface layer may determine the dendrite growth velocity difference for various refractory metals.

KW - Molecular dynamics

KW - Rapid dendritic growth

KW - Refractory metals

KW - Undercooling

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DO - 10.1016/j.cplett.2020.137141

M3 - 文章

AN - SCOPUS:85078240146

SN - 0009-2614

VL - 742

JO - Chemical Physics Letters

JF - Chemical Physics Letters

M1 - 137141

ER -

Ultrafast growth kinetics of titanium dendrites investigated by electrostatic levitation experiments and molecular dynamics simulations

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