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Shape Memory and Superelasticity

Erschienen in:

17.01.2023 | REVIEW

The Contributions by Kazuhiro Otsuka to “Shape Memory and Superelasticity”: A Review

verfasst von: T. R. Finlayson

Erschienen in: Shape Memory and Superelasticity | Ausgabe 2/2023

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Abstract

In this review, the research during the 50-year career in shape memory and superelasticity of Kazuhiro Otsuka is discussed, with a focus on his most cited publications. Not only did his research, in collaboration with many fellow scientists, explain the scientific basis for these phenomena, but also it has led to the realisation of a new aspect of the science of shape memory, particularly with regard to the physics of the most important Ti–Ni alloys, from the point of view of shape memory applications, as the result of the discovery of strain glass materials as a subset of shape memory behaviour for off-stoichiometric Ti_50-xNi_50+x compositions.

Vorheriger Artikel Honoring Professor Kazuhiro Otsuka for His 50 Years of Research on Shape Memory Alloys

Nächster Artikel Superelasticity Induced by a Strain Gradient

Otsuka K, Wayman CM (eds) (1988) Shape memory materials. Cambridge University Press, Cambridge

Otsuka K, Wayman CM (1967) Epitaxial growth of vacuum-evaporated Co on NaCl I. Conditions leading to epitaxy. Phys Stat Sol 22:559–578

Otsuka K, Wayman CM (1967) Epitaxial growth of vacuum-evaporated Co on NaCl II. Analysis of diffraction patterns. Phys Stat Sol 22:579–592

Shimizu K, Wayman CM (1966) Discussion of “Factors determining twinning in martensites.” Acta Metall 14:1390–1391

Rachinger WA (1958) A “super-elastic” single crystal calibration bar. Brit J Appl Phys 9:250–252

Duggin MJ, Rachinger WA (1964) The nature of the martensitic transformation in a copper-nickel-aluminium alloy. Acta Met 12:529–535

Otsuka K, Shimizu K (1969) Morphology and crystallography of thermoelastic γ´ Cu–Al–Ni martensite. Jap J Appl Phys 8:1196–1204

Otsuka K, Shimizu K (1970) Memory effect and thermoelastic martensitic transformation in Cu–Al–Ni alloy. Scripta Metall 4:469–472

Otsuka K (1971) Origin of the memory effect in Cu–Al–Ni alloy. Japan J Appl Phys 10(5):571–579

10.

Otsuka K, Shimizu K (1974) Morphology and crystallography of thermoelastic Cu–Al–Ni martensite analysed by the phenomenological theory. Trans Jpn Inst Metals 15:103–108

11.

Wechsler MS, Lieberman DS, Read TA (1953) On the theory of the formation of martensite. Trans AIME 197:1503–1515

12.

Bowles JS, McKenzie JK (1954) The crystallography of martensitic transformations I. Acta Met 2:129–137

13.

McKenzie JK, Bowles JS (1954) The crystallography of martensitic transformations II. Acta Met 2:138–147

14.

Sakamoto H, Otsuka K, Shimizu K (1977) Rubber-like behaviour in a Cu–Al–Ni alloy. Scripta Met 11:607–611

15.

Otsuka K, Wayman CM, Nakai K, Sakamoto H, Shimizu K (1976) Superelastic effects and stress-induced martensitic transformations in Cu–Al–Ni alloy. Acta Met 24:207–226

16.

Otsuka K, Sakamoto H, Shimizu K (1976) Two stage superelasticity effects and stress-induced martensitic transformations in Cu–Al–Ni alloy. Scripta Met 10(11):983–988

17.

Shimizu K, Sakamoto H, Otsuka K (1978) Phase diagram associated with stress-induced martensitic transformation in a Cu–Al–Ni alloy. Scripta Met 12(9):771–776

18.

Otsuka K, Sakamoto H, Shimizu K (1979) Stress-induced martensitic transformations and associated transformation pseudoelasticity in Cu–Al–Ni alloys. Acta Met 27:585–601

19.

Otsuka K, Tokonami M, Shimizu K, Iwata Y, Shibuya I (1979) Structure analysis of stress-induced β₁“ martensite in a Cu–Al–Ni alloy by neutron diffraction. Acta Met 27:965–972

20.

Baron A (2022) A brief history of nitinol – Kellogs Research Labs. https://www.kelloggsresearchlabs.com/2018/01/10/brief-history-of-nitinol/. Accessed 27 Sept 2022

21.

Otsuka K, Sawamura T, Shimizu K (1971) Crystal structure and internal defects of equiatomic TiNi martensite. Phys Stat Sol (a) 5:457–470

22.

Otsuka K, Sawamura T, Shimizu K, Wayman CM (1971) Characteristics of the martensitic transformation in TiNi and the memory effect. Met Trans 2:2583–2588

23.

Kudoh Y, Tokonami M, Miyazaki S, Otsuka K (1985) Crystal structure of the martensite in Ti-49.2 at.%Ni alloy analysed by the single crystal X-ray diffraction method. Acta Metall 33(11):2049–2056

24.

Miyazaki S, Otsuka K, Suzuki Y (1981) Transformation pseudoplasticity and deformation behaviour in a Ti-50.6at.% Ni alloy. Scripta Metall 15:287–292

25.

Takei F, Miura T, Miyazaki S, Kimura S, Otsuka K, Suzuki Y (1983) Stress-induced martensitic transformation in a Ti–Ni single crystal. Scripta Met 17:987–992

26.

Miyazaki S, Otsuka K (1986) Deformation and transition behaviour associated with the R-phase in Ti–Ni alloys. Met Trans A 17A:53–63

27.

Miyazaki S, Igo Y, Otsuka K (1986) Effect of thermal cycling on the transformation temperature of Ti–Ni alloys. Acta Metall 34(10):2045–2051

28.

Miyazaki S, Imai T, Igo Y, Otsuka K (1986) Effect of cyclic deformation on the pseudoelasticity characteristics of Ti–Ni alloys. Met Trans A 17A:115–120

29.

Matsumoto O, Miyazaki S, Otsuka K, Tamura H (1987) Crystallography of martensitic transformation in Ti–Ni single crystals. Acta Metall 35(8):2537–2144

30.

Miyazaki S, Kimura S, Otsuka K (1988) Shape-memory effect and pseudoelasticity associated with the R-phase transition in Ti-50.5at%Ni single crystals. Phil Mag A 57(3):467–478

31.

Miyazaki S, Otsuka K, Wayman CM (1989) The shape memory mechanism associated with the martensitic transformation in Ti–Ni alloys – I. Self accommodation Acta Metall 37(7):1873–1884

32.

Miyazaki S, Otsuka K, Wayman CM (1989) The shape memory mechanism associated with the martensitic transformation in Ti–Ni alloys – II. Variant coalescence and shape recovery. Acta Metall 37(7):1885–1890

33.

Hara T, Ohba T, Okunishi E, Otsuka K (1997) Structural study of R-phase in Ti-50.23at%Ni and Ti-47.75at%Ni-1.50at%Fe alloys. Mater Trans JIM 38(1):11–17

34.

Tanner LE, Soffa WA (1988) Foreward. Met Trans 19(4):760

35.

Tanner LE, Wayman CM (1981) Foreward. Met Trans 12A(4):558

36.

Otsuka K, Kubo H, Wayman CM (1981) Diffuse electron scattering and “streaming” effects. Met Trans 12A(4):595–605

37.

Tanner LE, Schryvers D, Shapero SM (1990) Electron microscopy and neutron scattering studies of premartensitic behaviour in ordered Ni-Al β₂ phase. Mater Sci Eng A127:205–213

38.

Tanner LE (1966) Diffraction contrast from elastic shear strains due to coherent phases. Phil Mag 14:111–130

39.

Otsuka K (1990) Crystallography of martensitic transformations and lattice invariant shears. Mater Sci Forum 56–58:393–404

40.

Shapiro SM (1990) Neutron scattering studies of premartensitic phenomena. Mater Sci Forum 56–58:33–44

41.

Finlayson TR, Liu M, Smith TF (1994) Thermal expansion and phonon anomalies near martensitic transformations. Advanced materials ’93 V/B. In: Otsuka K, Fuka Y (eds) Shape memory materials and hydrides, vol 18B. Elsevier Science Transactions of the Materials Research Society of Japan, Amsterdam, pp 835–838

42.

Dianoux A-J, Lander G (eds) (2002) Neutron data booklet. Institute Laue-Langevin, Grenoble, pp 11–12

43.

Ohba T, Shapiro SM, Aoki S, Otsuka K (1994) Phonon softening in Au-49.5at%Cd alloy. Jpn J Appl Phys 33:L631–L633

44.

Ohba T, Finlayson TR, Otsuka K (1995) Diffraction profile change in Au-Cu-Zn alloy with aging. ICOMAT 95, eds R. Gotthardt and J. Van Humbeeck, J. de Physique IV (Colloque C8) suppl. J Physique III 5:C8-1083-C8-1086

45.

Toyoshima N, Harada K, Abe H, Ohshima K, Suzuki T, Wuttig M, Finlayson T (1994) X-ray diffraction study of martensitic phase transformation in In-23at%Tl alloy. J Phys Soc Jpn 63:1803–1813

46.

Otsuka K, Kakeshita T (2002) Science and technology of shape-memory alloys: new developments. MRS Bull 27(2):91–98

47.

Duerig T (2002) The use of superelasticity in modern medicine. MRS Bull 27(2):101–104

48.

Otsuka K, Ren X (2005) Physical metallurgy of Ti–Ni-based shape memory alloys. Progress in Mater Sci 50:511–678

49.

Pelton AR, Berg BT, Saffari P, Stebner AP, Bucsek AN (2022) Pre-strain and mean strain effects on the fatigue behaviour of superelastic nitinol medical devices. Shape Mem Superelasticity 8:64–84. https://doi.org/10.1007/s40830-022-00377-yCrossRef

50.

Sarkar S, Ren X, Otsuka K (2005) Evidence for strain glass in the ferroelastic-martensitic system Ti_50-xNi_50+x. Phys Rev Lett 95:205702. https://doi.org/10.1103/PhysRevLett.95.205702CrossRef

51.

Kartha S, Castan T, Krumhansl JA, Sethna JP (1991) Spin-glass nature of tweed precursors in martensitic transformations. Phys Rev Lett 67(25):3630–3633

52.

Kartha S, Krumhansl JA, Sethna JA, Wickham LK (1995) Disorder-driven pretransitional tweed pattern in martensitic transformations. Phys Rev B 52(2):803–822

53.

Ren X, Wang Y, Zhou Y, Zhang Z, Wang D, Fan G, Otsuka K, Suzuki T, Ji Y, Zhang J, Tian Y, Hou S, Ding X (2010) Strain glass in ferroelastic systems: Premartensitic tweed versus strain glass. Phil Mag. https://doi.org/10.1080/14786430903074771CrossRef

54.

Wang Y, Ren X, Otsuka K (2006) Shape memory effect and superelasticity in a strain glass alloy. Phys Rev Lett 97:225703. https://doi.org/10.12103/PhysRevLett.97.225703CrossRef

55.

Zhang Z, Wang Y, Wang D, Zhou Y, Otsuka K, Ren X (2010) Phase diagram of Ti₅₀_-xNi_50+x: crossover from martensite to strain glass. Phys Rev B 81:224102. https://doi.org/10.1103/PhysRevB.81.224102CrossRef

56.

Zhou Y, Xue D, Tian Y, Ding X, Guo S, Otsuka K, Sun J, Ren X (2014) Direct evidence for local symmetry breaking during a strain glass transition. Phys Rev Lett. https://doi.org/10.1103/PhysRevLett.112.025701CrossRef

57.

Wang W, Ji Y, Fang M, Wang D, Ren S, Otsuka K, Wang Y, Ren X (2022) Reentrant strain glass transition in Ti–Ni-Cu shape memory alloy. Acta Mater. https://doi.org/10.1016/j.act.mat.2022.117618CrossRef

58.

Otsuka K, Saxena A, Deng J, Ren X (2011) Mechanism of the shape memory effect in martensitic alloys: an assessment. Phil Mag. https://doi.org/10.1080/14786435.2011.608735CrossRef

59.

Duerig TW (1990) Applications of shape memory. Mater Sci Forum 56–58:679–692

60.

Balasubramanian M, Srimath R, Vignesh L, Rajesh S (2021) Application of shape memory alloys in engineering—A review. J Phys Conf Ser. https://doi.org/10.1088/1742-6596/2054/1/012078CrossRef

61.

Ohba T (ed) (2002) A tribute to the work of Professor Kazuhiro Otsuka. University of Tsukuba, Tsukuba

62.

Krumhansl JA (2000) Multiscale science: Materials in the 21st century. In: Saburi T (ed.) Shape Memory Materials, – Proceedings of the International Symposium and Exhibition on Shape Memory Materials (SMM ’99) held in Kanazawa, Japan, in May 1999, Mater. Sci. Forum vol 327–328, pp 1–8

Titel: The Contributions by Kazuhiro Otsuka to “Shape Memory and Superelasticity”: A Review
verfasst von: T. R. Finlayson
Publikationsdatum: 17.01.2023
Verlag: Springer US
Erschienen in: Shape Memory and Superelasticity / Ausgabe 2/2023
Print ISSN: 2199-384X
Elektronische ISSN: 2199-3858
DOI: https://doi.org/10.1007/s40830-022-00406-w

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