Modeling solid-solid phase transformations: From single crystal to polycrystal behavior

R. C. Albers; R. Ahluwalia; T. Lookman; A. Saxena

doi:10.1590/s1807-03022004000200013

Modeling solid-solid phase transformations: From single crystal to polycrystal behavior

R. C. Albers
, R. Ahluwalia
, T. Lookman
, A. Saxena

Los Alamos National Laboratory Theoretical Division

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

8 Scopus citations

Abstract

We introduce a framework for modeling elastic properties of shape memory alloy polycrystals by coupling orientational degrees of freedom with elastic strains. Our method allows us to span the length scales from single crystal to that appropriate to obtain polycrystal properties. The single crystal free energy coefficients can be determined from microscopic calculations (such as electronic structure and molecular dynamics) and/or available experimental structural, phonon and thermodynamic data. We simulate the microstructure and determine the stress-strain response of the polycrystal and compare it with that of a single crystal. For FePd parameters we find that the recoverable strain for a polycrystal is ∼ 40% of that for a single crystal. The polycrystal information can, in principle, serve as input to the engineering scale of calculation, where the finite element method is appropriate.

Original language	English
Pages (from-to)	345-361
Number of pages	17
Journal	Computational and Applied Mathematics
Volume	23
Issue number	2-3
DOIs	https://doi.org/10.1590/s1807-03022004000200013
State	Published - 2004
Externally published	Yes

Keywords

Landau theory PACS: 81.30.Kf, 64.70.Kb, 61.72.Mm
Martensites
Polycrystals
Shape memory alloys

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10.1590/s1807-03022004000200013

Cite this

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title = "Modeling solid-solid phase transformations: From single crystal to polycrystal behavior",

abstract = "We introduce a framework for modeling elastic properties of shape memory alloy polycrystals by coupling orientational degrees of freedom with elastic strains. Our method allows us to span the length scales from single crystal to that appropriate to obtain polycrystal properties. The single crystal free energy coefficients can be determined from microscopic calculations (such as electronic structure and molecular dynamics) and/or available experimental structural, phonon and thermodynamic data. We simulate the microstructure and determine the stress-strain response of the polycrystal and compare it with that of a single crystal. For FePd parameters we find that the recoverable strain for a polycrystal is ∼ 40\% of that for a single crystal. The polycrystal information can, in principle, serve as input to the engineering scale of calculation, where the finite element method is appropriate.",

keywords = "Landau theory PACS: 81.30.Kf, 64.70.Kb, 61.72.Mm, Martensites, Polycrystals, Shape memory alloys",

author = "Albers, \{R. C.\} and R. Ahluwalia and T. Lookman and A. Saxena",

note = "Publisher Copyright: {\textcopyright} 2004 SBMAC.",

year = "2004",

doi = "10.1590/s1807-03022004000200013",

language = "英语",

volume = "23",

pages = "345--361",

journal = "Computational and Applied Mathematics",

issn = "2238-3603",

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}

TY - JOUR

T1 - Modeling solid-solid phase transformations

T2 - From single crystal to polycrystal behavior

AU - Albers, R. C.

AU - Ahluwalia, R.

AU - Lookman, T.

AU - Saxena, A.

PY - 2004

Y1 - 2004

N2 - We introduce a framework for modeling elastic properties of shape memory alloy polycrystals by coupling orientational degrees of freedom with elastic strains. Our method allows us to span the length scales from single crystal to that appropriate to obtain polycrystal properties. The single crystal free energy coefficients can be determined from microscopic calculations (such as electronic structure and molecular dynamics) and/or available experimental structural, phonon and thermodynamic data. We simulate the microstructure and determine the stress-strain response of the polycrystal and compare it with that of a single crystal. For FePd parameters we find that the recoverable strain for a polycrystal is ∼ 40% of that for a single crystal. The polycrystal information can, in principle, serve as input to the engineering scale of calculation, where the finite element method is appropriate.

AB - We introduce a framework for modeling elastic properties of shape memory alloy polycrystals by coupling orientational degrees of freedom with elastic strains. Our method allows us to span the length scales from single crystal to that appropriate to obtain polycrystal properties. The single crystal free energy coefficients can be determined from microscopic calculations (such as electronic structure and molecular dynamics) and/or available experimental structural, phonon and thermodynamic data. We simulate the microstructure and determine the stress-strain response of the polycrystal and compare it with that of a single crystal. For FePd parameters we find that the recoverable strain for a polycrystal is ∼ 40% of that for a single crystal. The polycrystal information can, in principle, serve as input to the engineering scale of calculation, where the finite element method is appropriate.

KW - Landau theory PACS: 81.30.Kf, 64.70.Kb, 61.72.Mm

KW - Martensites

KW - Polycrystals

KW - Shape memory alloys

UR - https://www.scopus.com/pages/publications/53349135114

U2 - 10.1590/s1807-03022004000200013

DO - 10.1590/s1807-03022004000200013

M3 - 文章

AN - SCOPUS:53349135114

SN - 2238-3603

VL - 23

SP - 345

EP - 361

JO - Computational and Applied Mathematics

JF - Computational and Applied Mathematics

IS - 2-3

ER -

Modeling solid-solid phase transformations: From single crystal to polycrystal behavior

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Keywords

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