Theory of phase transformation and reorientation in single crystalline shape memory alloys

J. J. Zhu; N. G. Liang; M. Cai; K. M. Liew; W. M. Huang

doi:10.1088/0964-1726/17/01/015041

Theory of phase transformation and reorientation in single crystalline shape memory alloys

J. J. Zhu, N. G. Liang, M. Cai, K. M. Liew, W. M. Huang

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

5 Citations (Scopus)

Abstract

A constitutive model, based on an (n+1)-phase mixture of the Mori-Tanaka average theory, has been developed for stress-induced martensitic transformation and reorientation in single crystalline shape memory alloys. Volume fractions of different martensite lattice correspondence variants are chosen as internal variables to describe microstructural evolution. Macroscopic Gibbs free energy for the phase transformation is derived with thermodynamics principles and the ensemble average method of micro-mechanics. The critical condition and the evolution equation are proposed for both the phase transition and reorientation. This model can also simulate interior hysteresis loops during loading/unloading by switching the critical driving forces when an opposite transition takes place. © IOP Publishing Ltd.

Original language	English
Article number	15041
Journal	Smart Materials and Structures
Volume	17
Issue number	1
DOIs	https://doi.org/10.1088/0964-1726/17/01/015041
Publication status	Published - 1 Feb 2008

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abstract = "A constitutive model, based on an (n+1)-phase mixture of the Mori-Tanaka average theory, has been developed for stress-induced martensitic transformation and reorientation in single crystalline shape memory alloys. Volume fractions of different martensite lattice correspondence variants are chosen as internal variables to describe microstructural evolution. Macroscopic Gibbs free energy for the phase transformation is derived with thermodynamics principles and the ensemble average method of micro-mechanics. The critical condition and the evolution equation are proposed for both the phase transition and reorientation. This model can also simulate interior hysteresis loops during loading/unloading by switching the critical driving forces when an opposite transition takes place. {\textcopyright} IOP Publishing Ltd.",

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AU - Zhu, J. J.

AU - Liang, N. G.

AU - Cai, M.

AU - Liew, K. M.

AU - Huang, W. M.

PY - 2008/2/1

Y1 - 2008/2/1

N2 - A constitutive model, based on an (n+1)-phase mixture of the Mori-Tanaka average theory, has been developed for stress-induced martensitic transformation and reorientation in single crystalline shape memory alloys. Volume fractions of different martensite lattice correspondence variants are chosen as internal variables to describe microstructural evolution. Macroscopic Gibbs free energy for the phase transformation is derived with thermodynamics principles and the ensemble average method of micro-mechanics. The critical condition and the evolution equation are proposed for both the phase transition and reorientation. This model can also simulate interior hysteresis loops during loading/unloading by switching the critical driving forces when an opposite transition takes place. © IOP Publishing Ltd.

AB - A constitutive model, based on an (n+1)-phase mixture of the Mori-Tanaka average theory, has been developed for stress-induced martensitic transformation and reorientation in single crystalline shape memory alloys. Volume fractions of different martensite lattice correspondence variants are chosen as internal variables to describe microstructural evolution. Macroscopic Gibbs free energy for the phase transformation is derived with thermodynamics principles and the ensemble average method of micro-mechanics. The critical condition and the evolution equation are proposed for both the phase transition and reorientation. This model can also simulate interior hysteresis loops during loading/unloading by switching the critical driving forces when an opposite transition takes place. © IOP Publishing Ltd.

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DO - 10.1088/0964-1726/17/01/015041

M3 - RGC 21 - Publication in refereed journal

SN - 0964-1726

VL - 17

JO - Smart Materials and Structures

JF - Smart Materials and Structures

IS - 1

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ER -

Theory of phase transformation and reorientation in single crystalline shape memory alloys

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