J. A. Klostermann, The concept of the habit plane and the phenomenological theories of the martensite transformation, Journal of the Less Common Metals, vol.28, issue.1, pp.75-94, 1972.
DOI : 10.1016/0022-5088(72)90170-1

D. S. Lieberman, M. S. Wechsler, and T. A. Read, Cubic to Orthorhombic Diffusionless Phase Change- 382

, Experimental and Theoretical Studies of AuCd, Journal of Applied Physics, vol.26, issue.4, pp.473-484, 1955.

W. Sinkler and D. Luzzi, An electron diffraction investigation of the diffuse ?? structure in quenched Ti-3d transition metal alloys, Acta Metallurgica et Materialia, vol.42, issue.4, pp.1249-1260, 1994.
DOI : 10.1016/0956-7151(94)90141-4

P. D. Frost, W. M. Parris, D. L. Hirsh, J. R. Diog, and C. M. Schwattz, Isothermal transformation of 386 titanium-chromium alloys, Transactions of the American Society for Metals, pp.46-231, 1954.

T. Yamamoto, K. Hayashi, N. Happo, S. Hosokawa, and H. Tajiri, Local atomic structure near an Nb atom in aged 388

?. Ti, S. Shin, C. Zhang, and K. S. Vecchio, Phase stability dependence of deformation mode correlated mechanical 390 properties and elastic properties in Ti-Nb gum metal, Materials Science and Engineering: A 702 (2017) 173-183 Shock-induced deformation twinning and omega transformation in tantalum and 392 tantalum-tungsten alloys, Acta Materialia Acta Materialia, vol.131, issue.391, pp.534-542, 2000.

G. K. Dey, R. Tewari, S. Banerjee, G. Jyoti, S. C. Gupta et al., Formation of a shock 394 deformation induced ? phase in Zr 20 Nb alloy Shock-induced displacive transformations in Tantalum and Tantalum-Tungsten 396 alloys Experimental 398 evidence of concurrent compositional and structural instabilities leading to ? precipitation in titanium? 399 molybdenum alloys, Acta Materialia Acta Metallurgica Acta Materialia, vol.52, issue.60211, pp.5243-5254, 1998.

R. Banerjee, S. A. Mantri, D. Choudhuri, T. Alam, V. Ageh et al., Coupled experimental and computational investigation of omega phase evolution in a high misfit 402 titanium-vanadium alloy, Change in the deformation mode 404 resulting from beta-omega compositional partitioning in a TiMo alloy: Room versus elevated temperature, pp.215-228, 2017.

H. Liu, M. Niinomi, M. Nakai, K. Cho, and H. Fujii, Athermal and deformation-induced ?-phase transformations in 407 biomedical beta-type alloy Ti?9Cr?0.2O Deformation-induced ?-phase transformation in a ?-type 409 titanium alloy during tensile deformation, 410 [15] M. Tane, T. Nakano, S. Kuramoto, M. Niinomi, N. Takesue, H. Nakajima, ? Transformation in cold-worked 411, pp.69-73, 2016.

]. J. Zhang, C. C. Tasan, M. J. Lai, A. C. Dippel, D. Raabe et al., alloys with low body-centered cubic phase stability and its correlation with their elastic 412 properties) (2013) 139-150. 413 [16 Complexion-mediated martensitic phase 414 transformation in Titanium, Acta Materialia Nature Communication, vol.61, issue.8

A. C. Manuscript, , p.14

E. Yang, T. Bertrand, and . Gloriant, oxygen on omega phase stability in the Ti-29Nb-13Ta-4.6Zr alloy, pp.144-148, 2016.

]. M. Lai, C. C. Tasan, J. Zhang, B. Grabowski, L. F. Huang et al., Physical Review 419 Letters 117(24) (2016) 245501 Origin of shear induced ? to ? 421 transition in Ti?Nb-based alloys, System at the Origin of {332}<113>beta Twins Observed in Metastable beta Titanium Alloys Stacking solitons in ?-phase systems and quasielastic scattering, pp.55-63, 2015.

H. Xing, J. Sun-yang, G. P. Li, H. Wang, S. Q. Wu et al., Mechanical twinning and omega transition by <111> {112} shear in a metastable ? titanium 425 alloy Formation of zigzag-shaped {112}<111> 427 b mechanical twins in Ti-24 Zigzag configuration of mechanical twin and stress-induced 429, Physical Review B Applied Physics Letters Scripta Materialia, vol.18, issue.665, pp.3549-3558, 1978.

, Journal of Alloys and Compounds, vol.625, issue.430, pp.188-192, 2015.

Z. B. Hao, S. J. Zhang, R. Li, H. Yang, G. Zhan et al., Microstructure and mechanical behavior of a Ti?24Nb?4Zr?8Sn 433 alloy processed by warm swaging and warm rolling The dynamic response of a metastable ? Ti?Nb alloy to high strain 435 rates at room and elevated temperatures Role of oxygen in stress-induced ? phase transformation and 437 {332}<113> mechanical twinning in ?Ti?20V alloy, Castany, E. Bertrand, M. Cornen, T. Gloriant, Investigation of mechanical twinning ijn the 439, pp.122-128, 2014.

, 440 [29] O.Izumi, S. Hanada, Transmission electron microscopic observations of mechanical twinning in metastable 441 beta titanium alloys Twinning system selection in a metastable ?-titanium alloy by 443, Proceedings of the 13th World Conference on Titanium, pp.1783-1786, 1986.

A. A. Schmid-factor, P. Ramarolahy, F. Castany, P. Prima, I. Laheurte et al., Microstructure and mechanical 445 behavior of superelastic Ti-24Nb-0.5O and Ti-24Nb-0.5N biomedical alloys Nucleation Behaviour of beta to omega Phase 448 Transformations in beta-Type Ti-Mo Alloys Manufacture by selective laser melting and 452 mechanical behavior of a biomedical Ti, Sercombe, Processing and properties of topologically optimised biomedical Ti scaffolds manufactured by selective laser melting, pp.1110-1113, 2011.

P. Yang, M. Castany, F. Cornen, S. J. Prima, Y. L. Li et al., Characterization of the martensitic 459 transformation in the superelastic Ti?24Nb?4Zr?8Sn alloy by in situ synchrotron X-ray diffraction and dynamic 460 mechanical analysis, Acta Materialia, vol.642, issue.88, pp.268-278, 2015.

N. Prima, M. J. Lu, J. M. Kim, S. J. Cairney, R. Li et al., Tracing the coupled atomic shear and shuffle for a cubic 463 to a hexagonal crystal transition, Scripta Materialia, vol.133, issue.464, pp.70-74, 2017.

R. Li and . Yang, Elastically confined martensitic transformation at the nano-scale in a multifunctional titanium alloy, p.466

]. P. Castany, A. Ramarolahy, F. Prima, P. Laheurte, C. Curfs et al., In situ synchrotron X-ray diffraction 468 study of the martensitic transformation in superelastic Ti-24Nb-0.5N and Ti-24Nb-0.5O alloys Deformation induced martensite and superelasticity in a b-metastable titanium 471 alloy, Acta Materialia Acta Materialia Materials Science and Engineering A, vol.135, issue.291, pp.330-339, 2000.

, Mechanisms and Biocompatibility of the Superelastic Ti?, pp.23-23

]. G. Taylor, Thermally-activated deformation of BCC metals and alloys, situ TEM study of dislocation slip in a metastable ? titanium alloy, pp.18-28, 1992.
DOI : 10.1016/0079-6425(92)90004-Q

P. Castany, M. Besse, and T. Gloriant, In situ TEM study of dislocation slip in a metastable ?? titanium alloy, Scripta Materialia, vol.66, issue.6, pp.371-373, 2011.
DOI : 10.1016/j.scriptamat.2011.11.036

URL : https://hal.archives-ouvertes.fr/hal-00864935

E. Bertrand, P. Castany, Y. Yang, E. Menou, and T. Gloriant, Deformation twinning in the full-?? martensitic Ti? 484 25Ta?20Nb shape memory alloy, Acta Materialia Acta Materialia, vol.64, issue.485110, pp.345-355, 2014.

, Self-accommodation in Ti?Nb shape memory alloys, 2008.

R. W. Cahn51-]-a, . D. Crocker-]-r, R. J. Field, D. J. Mccabe, D. F. Alexander et al., Plastic deformation of alpha-uranium twinning and slip The crystallography of deformation twinning in alpha-uranium Deformation twinning and twinning related fracture in 493 coarse-grained ?-uranium, Composition dependent 495 crystallography of ??-martensite in Ti?Nb-based ?-titanium alloy, pp.4054-4064, 1953.

A. N. ,

A. C. Manuscript, , pp.3325-3350