Atomic scale computer simulation for early precipitation process of Ni75Al6V19 alloy

Yuhong Zhao; Hua Hou; Hong Xu; Yongxin Wang; Zheng Chen; Xiaodong Sun

Atomic scale computer simulation for early precipitation process of Ni₇₅Al₆V₁₉ alloy

Yuhong Zhao, Hua Hou, Hong Xu, Yongxin Wang, Zheng Chen, Xiaodong Sun

Queen Mary University of London Engineering School

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

2 Scopus citations

Abstract

The atomic scale computer simulation for the initial precipitation mechanism of Ni₇₅Al₆V₁₉ alloy was carried out for the first time by employing the microscopic diffusion equation. The initial precipitation process was investigated through simulating the atomic pictures and calculating the order parameters of the two kinds of ordered phases. Simulation results show that the γ′ ordered phase precipitated earlier than the θ ordered phase by congruent ordering + spinodal decomposition mechanism and thus produced a nonstoichiometric γ′ single ordered phase. Then, the nonstoichiometric θ phase precipitated by a non-classical nucleation and growth mechanism at the APBS of the γ′ phase.

Original language	English
Pages (from-to)	17-19
Number of pages	3
Journal	Journal of Materials Science and Technology
Volume	19
Issue number	SUPPL.
State	Published - Dec 2003

Keywords

γ′ (NiAl) ordered phase
θ (NiV) ordered phase
NiAlV alloy
Precipitation mechanism

Cite this

@article{52bbf13e64a04538a23c88a345b36a2a,

title = "Atomic scale computer simulation for early precipitation process of Ni75Al6V19 alloy",

abstract = "The atomic scale computer simulation for the initial precipitation mechanism of Ni75Al6V19 alloy was carried out for the first time by employing the microscopic diffusion equation. The initial precipitation process was investigated through simulating the atomic pictures and calculating the order parameters of the two kinds of ordered phases. Simulation results show that the γ′ ordered phase precipitated earlier than the θ ordered phase by congruent ordering + spinodal decomposition mechanism and thus produced a nonstoichiometric γ′ single ordered phase. Then, the nonstoichiometric θ phase precipitated by a non-classical nucleation and growth mechanism at the APBS of the γ′ phase.",

keywords = "γ′ (NiAl) ordered phase, θ (NiV) ordered phase, NiAlV alloy, Precipitation mechanism",

author = "Yuhong Zhao and Hua Hou and Hong Xu and Yongxin Wang and Zheng Chen and Xiaodong Sun",

year = "2003",

month = dec,

language = "英语",

volume = "19",

pages = "17--19",

journal = "Journal of Materials Science and Technology",

issn = "1005-0302",

publisher = "Chinese Society of Metals",

number = "SUPPL.",

}

TY - JOUR

T1 - Atomic scale computer simulation for early precipitation process of Ni75Al6V19 alloy

AU - Zhao, Yuhong

AU - Hou, Hua

AU - Xu, Hong

AU - Wang, Yongxin

AU - Chen, Zheng

AU - Sun, Xiaodong

PY - 2003/12

Y1 - 2003/12

N2 - The atomic scale computer simulation for the initial precipitation mechanism of Ni75Al6V19 alloy was carried out for the first time by employing the microscopic diffusion equation. The initial precipitation process was investigated through simulating the atomic pictures and calculating the order parameters of the two kinds of ordered phases. Simulation results show that the γ′ ordered phase precipitated earlier than the θ ordered phase by congruent ordering + spinodal decomposition mechanism and thus produced a nonstoichiometric γ′ single ordered phase. Then, the nonstoichiometric θ phase precipitated by a non-classical nucleation and growth mechanism at the APBS of the γ′ phase.

AB - The atomic scale computer simulation for the initial precipitation mechanism of Ni75Al6V19 alloy was carried out for the first time by employing the microscopic diffusion equation. The initial precipitation process was investigated through simulating the atomic pictures and calculating the order parameters of the two kinds of ordered phases. Simulation results show that the γ′ ordered phase precipitated earlier than the θ ordered phase by congruent ordering + spinodal decomposition mechanism and thus produced a nonstoichiometric γ′ single ordered phase. Then, the nonstoichiometric θ phase precipitated by a non-classical nucleation and growth mechanism at the APBS of the γ′ phase.

KW - γ′ (NiAl) ordered phase

KW - θ (NiV) ordered phase

KW - NiAlV alloy

KW - Precipitation mechanism

UR - http://www.scopus.com/inward/record.url?scp=3242762291&partnerID=8YFLogxK

M3 - 文章

AN - SCOPUS:3242762291

SN - 1005-0302

VL - 19

SP - 17

EP - 19

JO - Journal of Materials Science and Technology

JF - Journal of Materials Science and Technology

IS - SUPPL.

ER -

Atomic scale computer simulation for early precipitation process of Ni₇₅Al₆V₁₉ alloy

Abstract

Keywords

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