Heterogeneous nucleation and dendritic growth within undercooled liquid niobium under electrostatic levitation condition

S. J. Yang; L. Hu; L. Wang; B. Wei

doi:10.1016/j.cplett.2017.06.046

Heterogeneous nucleation and dendritic growth within undercooled liquid niobium under electrostatic levitation condition

S. J. Yang, L. Hu, L. Wang, B. Wei

School of Physical Science and Technology

Northwestern Polytechnical University Xian

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

19 Scopus citations

Abstract

The physical mechanisms of crystal nucleation and dendritic growth within undercooled niobium were systematically studied by electrostatic levitation and molecular dynamics methods. The maximum undercooling was achieved as 454 K (0.16T_m), while the hypercooling limit was determined as 706 K (0.26T_m). The undercooling probability displayed Poisson distribution and indicated the occurrence of heterogeneous nucleation. The calculated critical nucleus size reduced rapidly with undercooling and the solid-liquid interface energy was deduced to be 0.367 J m⁻². In addition, the dendritic growth velocity of pure niobium exhibited a power relation versus undercooling, and reached 41 m s⁻¹ at the maximum undercooling.

Original language	English
Pages (from-to)	316-320
Number of pages	5
Journal	Chemical Physics Letters
Volume	684
DOIs	https://doi.org/10.1016/j.cplett.2017.06.046
State	Published - 2017

Keywords

Crystal nucleation
Dendritic growth
Liquid undercooling
Refractory metal

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title = "Heterogeneous nucleation and dendritic growth within undercooled liquid niobium under electrostatic levitation condition",

abstract = "The physical mechanisms of crystal nucleation and dendritic growth within undercooled niobium were systematically studied by electrostatic levitation and molecular dynamics methods. The maximum undercooling was achieved as 454 K (0.16Tm), while the hypercooling limit was determined as 706 K (0.26Tm). The undercooling probability displayed Poisson distribution and indicated the occurrence of heterogeneous nucleation. The calculated critical nucleus size reduced rapidly with undercooling and the solid-liquid interface energy was deduced to be 0.367 J m−2. In addition, the dendritic growth velocity of pure niobium exhibited a power relation versus undercooling, and reached 41 m s−1 at the maximum undercooling.",

keywords = "Crystal nucleation, Dendritic growth, Liquid undercooling, Refractory metal",

author = "Yang, {S. J.} and L. Hu and L. Wang and B. Wei",

note = "Publisher Copyright: {\textcopyright} 2017",

year = "2017",

doi = "10.1016/j.cplett.2017.06.046",

language = "英语",

volume = "684",

pages = "316--320",

journal = "Chemical Physics Letters",

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T1 - Heterogeneous nucleation and dendritic growth within undercooled liquid niobium under electrostatic levitation condition

AU - Yang, S. J.

AU - Hu, L.

AU - Wang, L.

AU - Wei, B.

PY - 2017

Y1 - 2017

N2 - The physical mechanisms of crystal nucleation and dendritic growth within undercooled niobium were systematically studied by electrostatic levitation and molecular dynamics methods. The maximum undercooling was achieved as 454 K (0.16Tm), while the hypercooling limit was determined as 706 K (0.26Tm). The undercooling probability displayed Poisson distribution and indicated the occurrence of heterogeneous nucleation. The calculated critical nucleus size reduced rapidly with undercooling and the solid-liquid interface energy was deduced to be 0.367 J m−2. In addition, the dendritic growth velocity of pure niobium exhibited a power relation versus undercooling, and reached 41 m s−1 at the maximum undercooling.

AB - The physical mechanisms of crystal nucleation and dendritic growth within undercooled niobium were systematically studied by electrostatic levitation and molecular dynamics methods. The maximum undercooling was achieved as 454 K (0.16Tm), while the hypercooling limit was determined as 706 K (0.26Tm). The undercooling probability displayed Poisson distribution and indicated the occurrence of heterogeneous nucleation. The calculated critical nucleus size reduced rapidly with undercooling and the solid-liquid interface energy was deduced to be 0.367 J m−2. In addition, the dendritic growth velocity of pure niobium exhibited a power relation versus undercooling, and reached 41 m s−1 at the maximum undercooling.

KW - Crystal nucleation

KW - Dendritic growth

KW - Liquid undercooling

KW - Refractory metal

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DO - 10.1016/j.cplett.2017.06.046

M3 - 文章

AN - SCOPUS:85023189107

SN - 0009-2614

VL - 684

SP - 316

EP - 320

JO - Chemical Physics Letters

JF - Chemical Physics Letters

ER -

Heterogeneous nucleation and dendritic growth within undercooled liquid niobium under electrostatic levitation condition

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Keywords

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