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Volume 18 Issue 1
Feb.  2011
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Shuai Wang, Koichi Tsuchiya, Lei Wang, and Minoru Umemoto, Martensitic stabilization and defects induced by deformation in TiNi shape memory alloys, Int. J. Miner. Metall. Mater., 18(2011), No. 1, pp. 66-69. https://doi.org/10.1007/s12613-011-0401-5
Cite this article as:
Shuai Wang, Koichi Tsuchiya, Lei Wang, and Minoru Umemoto, Martensitic stabilization and defects induced by deformation in TiNi shape memory alloys, Int. J. Miner. Metall. Mater., 18(2011), No. 1, pp. 66-69. https://doi.org/10.1007/s12613-011-0401-5
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Martensitic stabilization and defects induced by deformation in TiNi shape memory alloys

  • 通讯作者:

    Lei Wang    E-mail: wanglei@mail.neu.edu.cn

  • Martensitic stabilization caused by deformation in a TiNi shape memory alloy was studied. Special attention was paid to the deformed microstructures to identify the cause of martensitic stabilization. Martensitic stabilization was demonstrated by differential scanning calorimetry for the tensioned TiNi shape memory alloy. Transmission electron microscopy revealed that antiphase boundaries were formed because of the fourfold dissociation of [110]B19’ super lattice dislocations and were preserved after reverse transformation due to the lattice correspondence. Martensitic stabilization was attributed to dislocations induced by deformation, which reduced the ordering degree of the microstructure, spoiled the reverse path from martensite to parent phase compared with thermoelastic transformation, and imposed resistance on phase transformation through the stress field.
  • Martensitic stabilization and defects induced by deformation in TiNi shape memory alloys

    + Author Affiliations
    • Martensitic stabilization caused by deformation in a TiNi shape memory alloy was studied. Special attention was paid to the deformed microstructures to identify the cause of martensitic stabilization. Martensitic stabilization was demonstrated by differential scanning calorimetry for the tensioned TiNi shape memory alloy. Transmission electron microscopy revealed that antiphase boundaries were formed because of the fourfold dissociation of [110]B19’ super lattice dislocations and were preserved after reverse transformation due to the lattice correspondence. Martensitic stabilization was attributed to dislocations induced by deformation, which reduced the ordering degree of the microstructure, spoiled the reverse path from martensite to parent phase compared with thermoelastic transformation, and imposed resistance on phase transformation through the stress field.
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