A new approach predicting the evolution of laminated nanostructures - Martensite in NiTi as an example

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A new approach predicting the evolution of laminated nanostructures - Martensite in NiTi as an example. / Petersmann, Manuel; Antretter, Thomas; Waitz, Thomas et al.
in: Modelling and simulation in materials science and engineering, Jahrgang 25.2017, Nr. February, 035004, 14.02.2017.

Publikationen: Beitrag in FachzeitschriftArtikelForschung(peer-reviewed)

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@article{12ebab3380ae44ea8c6ea5b5606c76ce,
title = "A new approach predicting the evolution of laminated nanostructures - Martensite in NiTi as an example",
abstract = "A model for laminated nanostructures, combining classical energy minimization with full-field finite element (FE) calculations in a computationally fullyautomated manner, is set up and used to quantitatively analyse the interaction of grains via self-accommodation of their transformation strains. The well established B2 to B19' martensitic phase transformation in nanocrystalline NiTi is treated as an exemplary case to demonstrate our new framework. A systematic search for an optimal energy minimizing transformation path is employed within a full-field model, including crystallographic transformation strains and fully anisotropic elastic constants, by using the Python scripting language. The microstructure is updated based on previous calculation results. The underlying incremental free energy minimization criterion naturally reproduces the transformation kinetics. The sequence of grains subjected to transformation as well as the selection of martensitic variants within the grains are obtained yielding the evolution of the total interface energy as well as the strain energy, dominating our approach.",
author = "Manuel Petersmann and Thomas Antretter and Thomas Waitz and Fischer, {Franz Dieter}",
year = "2017",
month = feb,
day = "14",
doi = "10.1088/1361-651X/aa5ab4",
language = "English",
volume = "25.2017",
journal = "Modelling and simulation in materials science and engineering",
issn = "0965-0393",
publisher = "IOP Publishing Ltd.",
number = "February",

}

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TY - JOUR

T1 - A new approach predicting the evolution of laminated nanostructures - Martensite in NiTi as an example

AU - Petersmann, Manuel

AU - Antretter, Thomas

AU - Waitz, Thomas

AU - Fischer, Franz Dieter

PY - 2017/2/14

Y1 - 2017/2/14

N2 - A model for laminated nanostructures, combining classical energy minimization with full-field finite element (FE) calculations in a computationally fullyautomated manner, is set up and used to quantitatively analyse the interaction of grains via self-accommodation of their transformation strains. The well established B2 to B19' martensitic phase transformation in nanocrystalline NiTi is treated as an exemplary case to demonstrate our new framework. A systematic search for an optimal energy minimizing transformation path is employed within a full-field model, including crystallographic transformation strains and fully anisotropic elastic constants, by using the Python scripting language. The microstructure is updated based on previous calculation results. The underlying incremental free energy minimization criterion naturally reproduces the transformation kinetics. The sequence of grains subjected to transformation as well as the selection of martensitic variants within the grains are obtained yielding the evolution of the total interface energy as well as the strain energy, dominating our approach.

AB - A model for laminated nanostructures, combining classical energy minimization with full-field finite element (FE) calculations in a computationally fullyautomated manner, is set up and used to quantitatively analyse the interaction of grains via self-accommodation of their transformation strains. The well established B2 to B19' martensitic phase transformation in nanocrystalline NiTi is treated as an exemplary case to demonstrate our new framework. A systematic search for an optimal energy minimizing transformation path is employed within a full-field model, including crystallographic transformation strains and fully anisotropic elastic constants, by using the Python scripting language. The microstructure is updated based on previous calculation results. The underlying incremental free energy minimization criterion naturally reproduces the transformation kinetics. The sequence of grains subjected to transformation as well as the selection of martensitic variants within the grains are obtained yielding the evolution of the total interface energy as well as the strain energy, dominating our approach.

UR - http://iopscience.iop.org/article/10.1088/1361-651X/aa5ab4

U2 - 10.1088/1361-651X/aa5ab4

DO - 10.1088/1361-651X/aa5ab4

M3 - Article

VL - 25.2017

JO - Modelling and simulation in materials science and engineering

JF - Modelling and simulation in materials science and engineering

SN - 0965-0393

IS - February

M1 - 035004

ER -