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Philosophical Magazine A Volume 47, 1983 - Issue 2

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Original Articles

Transformation behaviour of a Ti₅₀Ni₄₇Fe₃ alloy. III. Martensitic transformation

C. M. Hwang Materials Research Laboratory, University of Illinois at Urbana-Champaign, Urbana, Illinois, 61801, U.S.A.

M. B. Salamon Materials Research Laboratory, University of Illinois at Urbana-Champaign, Urbana, Illinois, 61801, U.S.A.

C. M. Wayman Materials Research Laboratory, University of Illinois at Urbana-Champaign, Urbana, Illinois, 61801, U.S.A.

Pages 177-191 | Received 30 Mar 1982, Accepted 23 Jul 1982, Published online: 01 Dec 2006

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https://doi.org/10.1080/01418618308245217

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Wonseok Kim, Nayoung Keum, Jinyoung Kim & Jaeil Kim. (2024) Effect of Fe Composition and Heat Treatment Temperature on the Transformation Temperature of R-Phase of Ti-Ni-Fe Alloy. Korean Journal of Metals and Materials 62:4, pages 251-256.
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Anupam K. Singh, Sanjay Singh & Dhananjai Pandey. (2021) Pair distribution function study of magnetic shape memory alloy: Evidence for the precursor state of the premartensite phase . Physical Review B 104:6.
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Y. Soejima, A. Heima, H. Akamine, T. Inamura & M. Nishida. (2020) Comparison of In Situ SEM and TEM Observations of Thermoelastic Martensitic Transformation in Ti–Ni Shape Memory Alloy. MATERIALS TRANSACTIONS 61:11, pages 2107-2114.
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Yu Zhang & Fu Shun Liu. (2014) Effects of Mechanical Treatment and Pre-Deformation on Shape Recovery Stress of Ti50Ni47Fe3 Shape Memory Alloy. Materials Science Forum 787, pages 267-274.
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O Benafan, W U Notardonato, B J Meneghelli & R Vaidyanathan. (2013) Design and development of a shape memory alloy activated heat pipe-based thermal switch. Smart Materials and Structures 22:10, pages 105017.
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S.F. Hsieh, Albert W.J. Hsue, S.L. Chen, M.H. Lin, K.L. Ou & P.L. Mao. (2013) EDM surface characteristics and shape recovery ability of Ti35.5Ni48.5Zr16 and Ni60Al24.5Fe15.5 ternary shape memory alloys. Journal of Alloys and Compounds 571, pages 63-68.
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H.O. Mosca, G. Bozzolo & M.F. del Grosso. (2012) Atomistic modeling of ternary additions to NiTi and quaternary additions to Ni–Ti–Pd, Ni–Ti–Pt and Ni–Ti–Hf shape memory alloys. Physica B: Condensed Matter 407:16, pages 3244-3247.
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B. D. Ingale, W. C. Wei, P. C. Chang, Y. K. Kuo & S. K. Wu. (2011) Anomalous transport and thermal properties of NiTi and with Cu and Fe-doped shape memory alloys near the martensitic transition. Journal of Applied Physics 110:11.
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Y.F. Zheng, B.B. Zhang, B.L. Wang, Y.B. Wang, L. Li, Q.B. Yang & L.S. Cui. (2011) Introduction of antibacterial function into biomedical TiNi shape memory alloy by the addition of element Ag. Acta Biomaterialia 7:6, pages 2758-2767.
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S.F. Hsieh, S.L. Chen, H.C. Lin, M.H. Lin, J.H. Huang & M.C. Lin. (2010) A study of TiNiCr ternary shape memory alloys. Journal of Alloys and Compounds 494:1-2, pages 155-160.
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Tokujiro Yamamoto, Hiroyuki Kato, Yoshihiro Murakami, Hisamichi Kimura & Akihisa Inoue. (2008) Martensitic transformation and microstructure of Ti-rich Ti–Ni as-atomized powders. Acta Materialia 56:20, pages 5927-5937.
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C.L. Tan, X.H. Tian, G.J. Ji, T.L. Gui & W. Cai. (2008) Elastic property and electronic structure of TiNiPt high-temperature shape memory alloys. Solid State Communications 147:1-2, pages 8-10.
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Q.S. Liu, X. Ma, C.X. Lin & Y.D. Wu. (2006) Effect of the heat treatment on the damping characteristics of the NiTi shape memory alloy. Materials Science and Engineering: A 438-440, pages 563-566.
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Changlong Tan, Wei Cai & Jingchuan Zhu. (2006) First‐principles study on the elastic properties and electronic structure of TiNi‐based ternary shape memory alloys. physica status solidi (b) 243:11.
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K. Otsuka & X. Ren. (2005) Physical metallurgy of Ti–Ni-based shape memory alloys. Progress in Materials Science 50:5, pages 511-678.
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S.F. Hsieh, S.K. Wu, H.C. Lin & C.H. Yang. (2005) Transformation sequence and second phases in ternary Ti–Ni–W shape memory alloys with less than 2 at.% W. Journal of Alloys and Compounds 387:1-2, pages 121-127.
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J. F. Wan, X. L. Lei, S. P. Chen & T. Y. Hsu. (2004) Electron–transverse acoustic phonon interaction in martensitic alloys. Physical Review B 70:1.
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S.F. Hsieh, S.K. Wu & H.C. Lin. (2002) Transformation temperatures and second phases in Ti–Ni–Si ternary shape memory alloys with Si≤2 at.%. Journal of Alloys and Compounds 339:1-2, pages 162-166.
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S.F Hsieh, S.K Wu & H.C Lin. (2002) Martensitic transformation of a Ti-rich Ti51Ni47Si2 shape memory alloy. Journal of Alloys and Compounds 335:1-2, pages 254-261.
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S Golyandin, S Kustov, K Sapozhnikov, M Parlinska, R Gotthardt, J Van Humbeeck & R De Batist. (2000) Structural anelasticity of NiTi during two-stage martensitic transformation. Journal of Alloys and Compounds 310:1-2, pages 312-317.
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S.F Hsieh & S.K Wu. (2000) Martensitic transformation of quaternary Ti50.5−XNi49.5ZrX/2HfX/2 (X=0–20 at.%) shape memory alloys. Materials Characterization 45:2, pages 143-152.
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Y.F Zheng, W Cai, J.X Zhang, L.C Zhao & H.Q Ye. (2000) Microstructural development inside the stress induced martensite variant in a Ti–Ni–Nb shape memory alloy. Acta Materialia 48:6, pages 1409-1425.
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M.P.J Punkkinen, K Kokko & I.J Väyrynen. (1998) Low-temperature specific heat of near-equiatomic Ni-rich B19′-TiNi-alloys. Solid State Communications 108:8, pages 567-571.
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H.J Liu & Y.Y Ye. (1998) Electronic structure and stability of Ti-based B2 shape-memory alloys: By LMTO-ASA. Solid State Communications 106:4, pages 197-202.
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Peter Filip & Karel Mazanec. (1996) The two way memory effect in TiNi alloys. Scripta Materialia 35:3, pages 349-354.
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E. L. Semenova, N. Yu. Rusetskaya, V. M. Petyukh & V. Ye. Listovnichiy. (1995) Ruthenium Effect on the Transformation in Equiatomic Titanium-Nickel Alloy. Platinum Metals Review 39:4, pages 174-179.
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F.F. Gong, G.J. Shen, H.M. Shen & Y.N. Wang. (1995) Crystal and domain structures in sputtered Ni-51.6 at% Ti shape memory alloy films. Materials Letters 23:1-3, pages 87-91.
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Ren-Der Jean & Jing-Bang Duh. (1995) The thermal cycling effect on Ti-Ni-Cu shape memory alloy. Scripta Metallurgica et Materialia 32:6, pages 885-890.
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Y.Q. Yang, H.S. Jia, Z.F. Zhang, H.M. Shen, A. Hu & Y.N. Wang. (1995) Transformations in sputter-deposited thin films of NiTi shape memory alloy. Materials Letters 22:3-4, pages 137-140.
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M.L. Marquina, M. Jiménez, V. Marquina, S. Aburto, R. Ridaura, R. Gómez, R. Escudero & D. Ríos-Jara. (1994) Structural transitions in a TiNiFe shape memory alloy. Materials Characterization 32:3, pages 189-193.
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H.C. Lin, S.K. Wu & J.C. Lin. (1994) The martensitic transformation in Ti-rich TiNi shape memory alloys. Materials Chemistry and Physics 37:2, pages 184-190.
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L. CZhao, C.S. Zhang & W. Cai. 1994. Ecomaterials. Ecomaterials 1081 1084 .

H.C. Lin & S.K. Wu. (1992) Effects of hot rolling on the martensitic transformation of an equiatomic TiNi alloy. Materials Science and Engineering: A 158:1, pages 87-91.
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H.C. Lin, S.K. Wu, T.S. Chou & H.P. Kao. (1991) The effects of cold rolling on the martensitic transformation of an equiatomic TiNi alloy. Acta Metallurgica et Materialia 39:9, pages 2069-2080.
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A. Szász. (1991) On the electronic stability of amorphous alloys. Journal of Non-Crystalline Solids 127:2, pages 121-129.
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Yoshiyuki Nakata, Tsugio Tadaki & Ken’ichi Shimizu. (1991) Atom Location of the Third Element in Ti–Ni–X Shape Memory Alloys Determined by the Electron Channelling Enhanced Microanalysis. Materials Transactions, JIM 32:7, pages 580-586.
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Tsugio Tadaki, Sukeyoshi Yamamoto & Ken'ichi Shimizu. (2011) A Martensite Peculiar to Thin Foils of a Ti 50 Ni 49 Fei Shape Memory Alloy . MRS Proceedings 246.
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C.Y. Xie, L.C. Zhao & T.C. Lei. (1990) Effect of Ti3Ni4 precipitates on the phase transitions in an aged Ti-51.8at% Ni shape memory alloy. Scripta Metallurgica et Materialia 24:9, pages 1753-1758.
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Y-H. Chiao & I-Wei Chen. (1990) Martensitic growth in ZrO2—An in situ, small particle, TEM study of a single-interface transformation. Acta Metallurgica et Materialia 38:6, pages 1163-1174.
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S. Mendelson. (1989) The lattice dynamical mean field criterion for low energy dislocation structure formation in shape memory alloys. Materials Science and Engineering: A 122:2, pages 137-152.
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C.Y. Xie, L.C. Zhao & T.C. Lei. (1989) Effect of precipitates on the electrical resistivity-temperature curves in an aged Ti-51.8 at % Ni shape memory alloy. Scripta Metallurgica 23:12, pages 2131-2136.
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Hitoshi Matsumoto. (1989) Detection of anomalous properties in a premartensitic phenomenon of NiTi enhanced by addition of aluminum. Physica B: Condensed Matter 160:2, pages 138-142.
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M. Nishida, C.M. Wayman & A. Chiba. (1988) Electron microscopy studies of the martensitic transformation in an aged Ti-51at%Ni shape memory alloy. Metallography 21:3, pages 275-291.
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M. Nishida & C.M. Wayman. (1988) Electron microscopy studies of the “Premartensitic” transformations in an aged Ti-51 at%Ni shape memory alloy. Metallography 21:3, pages 255-273.
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A. Szasz & DJ Fabian. (1988) On electronic structure and metastability. Solid State Communications 65:10, pages 1085-1088.
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M.L. Trudeau, R.W. Cochrane & J. Destry. (1988) The hall effect in paramagnetic CoZr metallic glasses. Materials Science and Engineering 99:1-2, pages 187-190.
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M.L. TRUDEAU, R.W. COCHRANE & J. DESTRY. 1988. Rapidly Quenched Metals 6. Rapidly Quenched Metals 6 187 190 .

S.K. Wu & C.M. Wayman. (1987) Transmission electron microscopy studies of the martensitic transformation in a Ti50Ni45Au5 alloy. Materials Science and Engineering 96, pages 295-302.
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C. Kim & C.M. Hwang. (1987) Electron microscopy studies of phase transformations in a Ti49.5Ni48Cr2.5 alloy. Scripta Metallurgica 21:7, pages 959-962.
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Li Xuemin & T.Y. Hsu(Xu Zuyao). (1987) An investigation of phase transformations in a 50.8at.%NiTi shape memory alloy. Materials Science and Engineering 91, pages 189-194.
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Li Xuemin & T.Y. Hsu (Xu Zuyao). (1987) In situ study of phase transformations in a 50.8 at.% Ni-Ti alloy. Metallography 20:1, pages 47-59.
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Tsunehiko TodorokiHirokazu Tamura. (1987) Effect of Heat Treatment after Cold Working on the Phase Transformation in TiNi Alloy. Transactions of the Japan Institute of Metals 28:2, pages 83-94.
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H. Beck & R. Frésard. 1987. Amorphous and Liquid Materials. Amorphous and Liquid Materials 321 332 .

G.J. Morgan, B.J. Hickey & S.A. Fairbairn. (1986) The localisation of electrons in structurally disordered systems. Journal of Non-Crystalline Solids 86:1-2, pages 80-87.
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Tsugio Tadaki, Yoshiyuki Nakata, Ken’ichi Shimizu & Kazuhiro Otsuka. (1986) Crystal Structure, Composition and Morphology of a Precipitate in an Aged Ti-51 at%Ni Shape Memory Alloy. Transactions of the Japan Institute of Metals 27:10, pages 731-740.
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M. B. Salamon, M. E. Meichle & C. M. Wayman. (1985) Premartensitic phases of . Physical Review B 31:11, pages 7306-7315.
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V. G. Pushin, V. V. Kondrat'ev & V. N. Khachin. (1985) Pretransformation phenomena and martensitic transformations in titanium nickelide alloys. Soviet Physics Journal 28:5, pages 341-355.
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E.M. Carvalho & I.R. Harris. (1985) Electrical resistivity studies of phase transitions in the system Zr50Co50−xNx (0⩽ x ⩽ 50): II. Journal of the Less Common Metals 106:1, pages 129-141.
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E.M. Carvalho & I.R. Harris. (1985) Magnetic susceptibility studies of phase transitions in the system Zr50Co50−xNix (0 ⩽ x ⩽ 50): I. Journal of the Less Common Metals 106:1, pages 117-128.
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M. Nishida, C.M. Wayman & T. Honma. (1984) Electron microscopy studies of the all-around shape memory effect in a Ti-51.0 at .%Ni alloy. Scripta Metallurgica 18:12, pages 1389-1394.
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P Moine, J Allain & B Renker. (1984) Observation of a soft-phonon mode and a pre-martensitic phase in the intermetallic compound Ti 50 Ni 47 Fe 3 studied by inelastic neutron scattering . Journal of Physics F: Metal Physics 14:11, pages 2517-2523.
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S. K. Satija, S. M. Shapiro, M. B. Salamon & C. M. Wayman. (1984) Phonon softening in . Physical Review B 29:11, pages 6031-6035.
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Norihiko Nakanishi, Masato Hayashi & Yuichiro Murakami. (1984) On the Nature of Martensitic Transformation in the Ternary Ni–Zn–Cu Alloys. Transactions of the Japan Institute of Metals 25:3, pages 135-141.
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C. M. Wayman. (2011) Modulated Microstructures in β-Phase Alloys. MRS Proceedings 39.
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C.M. Hwang & C.M. Wayman. (1984) Diffuse electron scattering from an incommensurate phase in a Ti58.7Ni37.5Al3.8 alloy. Acta Metallurgica 32:1, pages 183-187.
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G. F. Weir & G. J. Morgan. 1984. The Electronic Structure of Complex Systems. The Electronic Structure of Complex Systems 779 790 .

C.M. Hwang & C.W. Wayman. (1983) Electron microscopy studies of martensitic transformations in ternary TiNiAl alloys. Scripta Metallurgica 17:12, pages 1449-1453.
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C.M. Hwang & C.M. Wayman. (1983) Phase transformations in TiNiFe, TiNiAl and TiNi alloys. Scripta Metallurgica 17:11, pages 1345-1350.
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Heng Li, Xin Liu, Hao Guan, Zhiwei Yang, Yanhong Zhang, Qingfei Gu & Jingchao Yang. (2022) Degradation of Shape Memory Effects after Annealing Treatment in Hot-Forged Nitife Alloy. SSRN Electronic Journal.
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Transformation behaviour of a Ti₅₀Ni₄₇Fe₃ alloy. III. Martensitic transformation

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Transformation behaviour of a Ti50Ni47Fe3 alloy. III. Martensitic transformation

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Transformation behaviour of a Ti₅₀Ni₄₇Fe₃ alloy. III. Martensitic transformation