PDF
(1808KB)
Abstract
In the past years, shape memory alloys (SMAs) have found applications in numerous fields. The unique energy dissipation capacity of SMAs under cyclic loading and their notable super elasticity, along with their high reliability, make them an ideal candidate for use as an energy dissipation material and a passive vibration control solution. In vibration control implementation, because of the cyclic essence of applied dynamic forces, it is crucial to examine the mechanical behavior of SMAs under cyclic loading. Numerous researchers have dedicated their efforts to studying the cyclic behavior of superelastic SMAs, delving into the effect of various loading characteristics such as frequency and strain amplitude as well as the effect of specimen size and ambient temperature. While the primary focus of this paper is to review existing research on the mechanical behavior of NiTi SMA under strain-controlled cyclic loading, it also includes an overview of the phase transformation mechanism, which manifests itself as shape memory effects and superelasticity. This additional information is provided to deepen the understanding of SMA material behavior. The perspective and data presented in this paper are tailored to appeal to civil engineers, with a specific emphasis on the information of interest in this field.
Graphical abstract
Keywords
SMA
/
cyclic loading
/
energy dissipation
/
hysteresis stress–strain loops
/
superelasticity
Cite this article
Download citation ▾
Danial DAVARNIA, Shaohong CHENG, Niel VAN ENGELEN.
Mechanical behavior of NiTi shape memory alloy under cyclic loading: A state-of-the-art review.
Front. Struct. Civ. Eng., 2025, 19(7): 1041-1060 DOI:10.1007/s11709-025-1195-2
| [1] |
DuerigTPeltonAStöckelD. An overview of nitinol medical applications. Materials Science and Engineering A, 1999, 273–275: 149–160
|
| [2] |
ConcilioAAntonucciVAuricchioFLecceLSaccoE. Shape Memory Alloy Engineering: For Aerospace, Structural, and Biomedical Applications. London: Butterworth-Heinemannt, 2021
|
| [3] |
El Feninat F, Laroche G, Fiset M, Mantovani D. Shape memory materials for biomedical applications. Advanced Engineering Materials, 2002, 4(3): 91–104
|
| [4] |
Hartl D J, Lagoudas D C. Aerospace applications of shape memory alloys. Proceedings of the Institution of Mechanical Engineers, Part G: Journal of Aerospace Engineering, 2007, 221(4): 535–552
|
| [5] |
Strelec J K, Lagoudas D C, Khan M A, Yen J. Design and implementation of a shape memory alloy actuated reconfigurable airfoil. Journal of Intelligent Material Systems and Structures, 2003, 14(4–5): 257–273
|
| [6] |
OtsukaKWaymanC M. Shape Memory Materials. Cambridge: Cambridge University Press, 1999
|
| [7] |
ManiRLagoudasD CRediniotisO K. MEMS-based active skin for turbulent drag reduction. In: Smart Structures and Materials 2003: Smart Structures and Integrated Systems. Bellingham: SPIE, 2003, 9–20
|
| [8] |
Ozbulut O E, Hurlebaus S, Desroches R. Seismic response control using shape memory alloys: A review. Journal of Intelligent Material Systems and Structures, 2011, 22(14): 1531–1549
|
| [9] |
Motavalli M, Czaderski C, Bergamini A, Janke L. Shape memory alloys for civil engineering structures-on the way from vision to reality. Architecture Civil Engineering Environment, 2009, 2: 81–94
|
| [10] |
Alam M S, Youssef M A, Nehdi M. Utilizing shape memory alloys to enhance the performance and safety of civil infrastructure: A review. Canadian Journal of Civil Engineering, 2007, 34(9): 1075–1086
|
| [11] |
FangCWangW. Shape Memory Alloys for Seismic Resilience. Berlin: Springer, 2020
|
| [12] |
Shrestha K C, Araki Y, Nagae T, Koetaka Y, Suzuki Y, Omori T, Sutou Y, Kainuma R, Ishida K. Feasibility of Cu–Al–Mn superelastic alloy bars as reinforcement elements in concrete beams. Smart Materials and Structures, 2013, 22(2): 025025
|
| [13] |
Sawaguchi T, Maruyama T, Otsuka H, Kushibe A, Inoue Y, Tsuzaki K. Design concept and applications of Fe–Mn–Si-based alloys—from shape-memory to seismic response control. Materials Transactions, 2016, 57(3): 283–293
|
| [14] |
Ghafoori E, Wang B, Andrawes B. Shape memory alloys for structural engineering: An editorial overview of research and future potentials. Engineering Structures, 2022, 273: 115138
|
| [15] |
Ferretto I, Kim D, Mohri M, Ghafoori E, Lee W J, Leinenbach C. Shape recovery performance of a (V,C)-containing Fe–Mn–Si–Ni–Cr shape memory alloy fabricated by laser powder bed fusion. Journal of Materials Research and Technology, 2022, 20: 3969–3984
|
| [16] |
Huang H, Mosalam K M, Chang W S. Adaptive tuned mass damper with shape memory alloy for seismic application. Engineering Structures, 2020, 223: 111171
|
| [17] |
Zuo H, Bi K, Hao H, Li C. Numerical study of using shape memory alloy-based tuned mass dampers to control seismic responses of wind turbine tower. Engineering Structures, 2022, 250: 113452
|
| [18] |
Clark P W, Aiken I D, Kelly J M, Higashino M, Krumme R. Experimental and analytical studies of shape-memory alloy dampers for structural control. Smart Structures and Materials, 1995, 2445: 241–251
|
| [19] |
HigashinoMAizawaSClarkP WWhittakerA SAikenI DKellyJ M. Experimental and analytical studies of structural control system using shape memory alloy. In: Second International Workshop on Structural Control. 1996, 221–232
|
| [20] |
Krumme R, Hayes J, Sweeney S. Structural damping with shape-memory alloys: one class of devices. Smart Structures and Materials, 1995, 2445: 225–240
|
| [21] |
Aizawa S, Kakizawa T, Higasino M. Case studies of smart materials for civil structures. Smart Materials and Structures, 1998, 7(5): 617–626
|
| [22] |
Salichs J, Hou Z, Noori M. Vibration suppression of structures using passive shape memory alloy energy dissipation devices. Journal of Intelligent Material Systems and Structures, 2001, 12(10): 671–680
|
| [23] |
Xue S, Li X. Control devices incorporated with shape memory alloy. Earthquake Engineering and Engineering Vibration, 2007, 6(2): 159–169
|
| [24] |
Ma H, Yam M C H. Modelling of a self-centring damper and its application in structural control. Journal of Constructional Steel Research, 2011, 67(4): 656–666
|
| [25] |
Dolce M, Cardone D, Marnetto R. Implementation and testing of passive control devices based on shape memory alloys. Earthquake Engineering and Structural Dynamics, 2000, 29(7): 945–968
|
| [26] |
Han Y L, Xing D E J, Xiao E R T, Li A Q. NiTi-wire shape memory alloy dampers to simultaneously damp tension, compression, and torsion. Journal of Vibration and Control, 2005, 11(8): 1067–1084
|
| [27] |
Ma H, Cho C. Feasibility study on a superelastic SMA damper with re-centring capability. Materials Science and Engineering A, 2008, 473(1–2): 290–296
|
| [28] |
Walter Yang C S, DesRoches R, Leon R T. Design and analysis of braced frames with shape memory alloy and energy-absorbing hybrid devices. Engineering Structures, 2010, 32(2): 498–507
|
| [29] |
Zhang Y, Zhu S. A shape memory alloy-based reusable hysteretic damper for seismic hazard mitigation. Smart Materials and Structures, 2007, 16(5): 1603–1613
|
| [30] |
Speicher M, Hodgson D E, Desroches R, Leon R T. Shape memory alloy tension/compression device for seismic retrofit of buildings. Journal of Materials Engineering and Performance, 2009, 18(5-6): 746–753
|
| [31] |
Zhang S, Hou H, Qu B, Zhu Y, Li K, Fu X. Tests of a novel re-centering damper with SMA rods and friction wedges. Engineering Structures, 2021, 236: 112125
|
| [32] |
Saadat S, Noori M, Davoodi H, Hou Z, Suzuki Y, Masuda A. Using NiTi SMA tendons for vibration control of coastal structures. Smart Materials and Structures, 2001, 10(4): 695–704
|
| [33] |
Lafortune P, McCormick J, DesRoches R, Terriault P. Testing of superelastic recentering pre-strained braces for seismic resistant design. Journal of Earthquake Engineering, 2007, 11(3): 383–399
|
| [34] |
Auricchio F, Fugazza D, Desroches R. Earthquake performance of steel frames with nitinol braces. Journal of Earthquake Engineering, 2006, 10(s1): 45–66
|
| [35] |
Bartera F, Giacchetti R. Steel dissipating braces for upgrading existing building frames. Journal of Constructional Steel Research, 2004, 60(3–5): 751–769
|
| [36] |
Boroschek R L, Farias G, Moroni O, Sarrazin M. Effect of SMA braces in a steel frame building. Journal of Earthquake Engineering, 2007, 11(3): 326–342
|
| [37] |
Ozbulut O E, Roschke P N, Lin P Y, Loh C H. GA-based optimum design of a shape memory alloy device for seismic response mitigation. Smart Materials and Structures, 2010, 19(6): 065004
|
| [38] |
Ocel J, Desroches R, Leon R T, Hess W G, Krumme R, Hayes J R, Sweeney S. Steel beam-column connections using shape memory alloys. Journal of Structural Engineering, 2004, 130(5): 732–740
|
| [39] |
Ma H, Wilkinson T, Cho C. Feasibility study on a self-centering beam-to-column connection by using the superelastic behavior of SMAs. Smart Materials and Structures, 2007, 16(5): 1555–1563
|
| [40] |
Sepúlveda J, Boroschek R, Herrera R, Moroni O, Sarrazin M. Steel beam–column connection using copper-based shape memory alloy dampers. Journal of Constructional Steel Research, 2008, 64(4): 429–435
|
| [41] |
Youssef M A, Alam M S, Nehdi M. Experimental investigation on the seismic behavior of beam–column joints reinforced with superelastic shape memory alloys. Journal of Earthquake Engineering, 2008, 12(7): 1205–1222
|
| [42] |
DesRoches R, Taftali B, Ellingwood B R. Seismic performance assessment of steel frames with shape memory alloy connections. Part I—Analysis and seismic demands. Journal of Earthquake Engineering, 2010, 14(4): 471–486
|
| [43] |
Ellingwood B R, Taftali B, Desroches R. Seismic performance assessment of steel frames with shape memory alloy connections, Part II—Probabilistic seismic demand assessment. Journal of Earthquake Engineering, 2010, 14(5): 631–645
|
| [44] |
Cardone D, Dolce M, Ponzo F C. The behaviour of SMA isolation systems based on a full-scale release test. Journal of Earthquake Engineering, 2006, 10(6): 815–842
|
| [45] |
Dolce M, Cardone D, Ponzo F C. Shaking-table tests on reinforced concrete frames with different isolation systems. Earthquake Engineering and Structural Dynamics, 2007, 36(5): 573–596
|
| [46] |
El-Borgi S, Neifar M, Jabeur M B, Cherif D, Smaoui H. Use of copper shape memory alloys in retrofitting historical monuments. Smart Structures and Systems, 2008, 4(2): 247–259
|
| [47] |
El-Attar A, Saleh A, El-Habbal I, Zaghw A H, Osman A. The use of SMA wire dampers to enhance the seismic performance of two historical Islamic minarets. Smart Structures and Systems, 2008, 4(2): 221–232
|
| [48] |
Ghassemieh M, Rezapour M, Sadeghi V. Effectiveness of the shape memory alloy reinforcement in concrete coupled shear walls. Journal of Intelligent Material Systems and Structures, 2017, 28(5): 640–652
|
| [49] |
Abdulridha A, Palermo D. Behaviour and modelling of hybrid SMA-steel reinforced concrete slender shear wall. Engineering Structures, 2017, 147: 77–89
|
| [50] |
Zerbe L, Vieira D, Belarbi A, Senouci A. Uniaxial compressive behavior of circular concrete columns actively confined with Fe-SMA strips. Engineering Structures, 2022, 255: 113878
|
| [51] |
Jung D, Wilcoski J, Andrawes B. Bidirectional shake table testing of RC columns retrofitted and repaired with shape memory alloy spirals. Engineering Structures, 2018, 160: 171–185
|
| [52] |
Liu X, Li J, Tsang H H, Wilson J. Enhancing seismic performance of unbonded prestressed concrete bridge column using superelastic shape memory alloy. Journal of Intelligent Material Systems and Structures, 2018, 29(15): 3082–3096
|
| [53] |
Deng Z, Li Q, Sun H. Behavior of concrete beam with embedded shape memory alloy wires. Engineering Structures, 2006, 28(12): 1691–1697
|
| [54] |
Michels J, Shahverdi M, Czaderski C. Flexural strengthening of structural concrete with iron-based shape memory alloy strips. Structural Concrete, 2018, 19(3): 876–891
|
| [55] |
Cladera A, Montoya-Coronado L A, Ruiz-Pinilla J G, Ribas C. Shear strengthening of slender reinforced concrete T-shaped beams using iron-based shape memory alloy strips. Engineering Structures, 2020, 221: 111018
|
| [56] |
Chang W S, Murakami S, Komatsu K, Araki Y, Shrestha K, Omori T, Kainuma R. Technical note: Potential to use shape memory alloy in timber dowel-type connections. Wood and Fiber Science, 2013, 45: 330–334
|
| [57] |
van de Lindt J W, Potts A. Shake table testing of a superelastic shape memory alloy response modification device in a wood shearwall. Journal of Structural Engineering, 2008, 134(8): 1343–1352
|
| [58] |
Andrawes B, DesRoches R. Unseating prevention for multiple frame bridges using superelastic devices. Smart Materials and Structures, 2005, 14(3): S60–S67
|
| [59] |
Dezfuli F H, Alam M S. Seismic vulnerability assessment of a steel-girder highway bridge equipped with different SMA wire-based smart elastomeric isolators. Smart Materials and Structures, 2016, 25(7): 075039
|
| [60] |
Zhou H, Qi S, Yao G, Zhou L, Sun L, Xing F. Damping and frequency of a model cable attached with a pre-tensioned shape memory alloy wire: Experiment and analysis. Structural Control and Health Monitoring, 2018, 25(2): e2106
|
| [61] |
Yang X, Zhou H, Yang X, Zhou X, Zhang S Y, Du Y. Shape memory alloy strands as cross-ties: Fatigue behavior and model-cable net tests. Engineering Structures, 2021, 245: 112828
|
| [62] |
Zhou P, Liu M, Li H, Song G. Experimental investigations on seismic control of cable-stayed bridges using shape memory alloy self-centering dampers. Structural Control and Health Monitoring, 2018, 25(7): e2180
|
| [63] |
SharabashAAndrawesB. Seismic control of cable-stayed bridges using shape memory alloy dampers. In: The 14th Word Conference on Earthquake Engineering, Beijing, China. 2008
|
| [64] |
Tabrizikahou A, Kuczma M, Łasecka-Plura M, Noroozinejad Farsangi E, Noori M, Gardoni P, Li S. Application and modelling of Shape-Memory Alloys for structural vibration control: State-of-the-art review. Construction and Building Materials, 2022, 342: 127975
|
| [65] |
Sato A, Soma K, Chishima E, Mori T. Shape memory effect and mechanical behaviour of an Fe-30Mn-1Si alloy single crystal. Journal de Physique Colloque, 1982, 43(C4): 797–802
|
| [66] |
Dasgupta R. A look into Cu-based shape memory alloys: Present scenario and future prospects. Journal of Materials Research, 2014, 29(16): 1681–1698
|
| [67] |
Zareie S, Issa A S, Seethaler R J, Zabihollah A. Recent advances in the applications of shape memory alloys in civil infrastructures: A review. Structures, 2020, 27: 1535–1550
|
| [68] |
Abavisani I, Rezaifar O, Kheyroddin A. Multifunctional properties of shape memory materials in civil engineering applications: A state-of-the-art review. Journal of Building Engineering, 2021, 44: 102657
|
| [69] |
Mohammadgholipour A, Billah A M. Mechanical properties and constitutive models of shape memory alloy for structural engineering: A review. Journal of Intelligent Material Systems and Structures, 2023, 34(20): 2335–2359
|
| [70] |
Muntasir Billah A H M, Rahman J, Zhang Q. Shape memory alloys (SMAs) for resilient bridges: A state-of-the-art review. Structures, 2022, 37: 514–527
|
| [71] |
Song G, Ma N, Li H N. Applications of shape memory alloys in civil structures. Engineering Structures, 2006, 28(9): 1266–1274
|
| [72] |
Molod M A, Spyridis P, Barthold F J. Applications of shape memory alloys in structural engineering with a focus on concrete construction—A comprehensive review. Construction and Building Materials, 2022, 337: 127565
|
| [73] |
MennaCAuricchioFAsproneD. Applications of Shape Memory Alloys in Structural Engineering. Amsterdam: Elsevier, 2015, 369–403
|
| [74] |
Chowdhury P, Sehitoglu H. Deformation physics of shape memory alloys—Fundamentals at atomistic frontier. Progress in Materials Science, 2017, 88: 49–88
|
| [75] |
Tadaki T, Otsuka K, Shimizu K. Shape memory alloys. Annual Review of Materials Science, 1988, 18(1): 25–45
|
| [76] |
KumarP KLagoudasD C. Introduction to Shape Memory Alloys. Boston: Springer, 2008, 1–51
|
| [77] |
Nemat-Nasser S, Guo W G. Superelastic and cyclic response of NiTi SMA at various strain rates and temperatures. Mechanics of Materials, 2006, 38(5-6): 463–474
|
| [78] |
Motahari S A, Ghassemieh M, Abolmaali S A. Implementation of shape memory alloy dampers for passive control of structures subjected to seismic excitations. Journal of Constructional Steel Research, 2007, 63(12): 1570–1579
|
| [79] |
Shaw J A, Kyriakides S. Thermomechanical aspects of NiTi. Journal of the Mechanics and Physics of Solids, 1995, 43(8): 1243–1281
|
| [80] |
Ozbulut O E, Hurlebaus S. Neuro-fuzzy modeling of temperature- and strain-rate-dependent behavior of NiTi shape memory alloys for seismic applications. Journal of Intelligent Material Systems and Structures, 2010, 21(8): 837–849
|
| [81] |
Lu Z K, Weng G J. Martensitic transformation and stress–strain relations of shape-memory alloys. Journal of the Mechanics and Physics of Solids, 1997, 45(11-12): 1905–1928
|
| [82] |
Šittner P, Heller L, Pilch J, Curfs C, Alonso T, Favier D. Young’s Modulus of Austenite and Martensite Phases in Superelastic NiTi Wires. Journal of Materials Engineering and Performance, 2014, 23(7): 2303–2314
|
| [83] |
Mutlu F, Anlaş G, Moumni Z. Effect of loading rate on fracture mechanics of NiTi SMA. International Journal of Fracture, 2020, 224(2): 151–165
|
| [84] |
You Y, Gu X, Zhang Y, Moumni Z, Anlaş G, Zhang W. Effect of thermomechanical coupling on stress-induced martensitic transformation around the crack tip of edge cracked shape memory alloy. International Journal of Fracture, 2019, 216(1): 123–133
|
| [85] |
DesRoches R, McCormick J, Delemont M. Cyclic properties of superelastic shape memory alloy wires and bars. Journal of Structural Engineering, 2004, 130(1): 38–46
|
| [86] |
Wang L, Feng P, Wu Y, Liu Z. A tensile-compressive asymmetry model for shape memory alloys with a redefined martensite internal variable. Smart Materials and Structures, 2019, 28(10): 105050
|
| [87] |
Lin P H, Tobushi H, Tanaka K, Hattori T, Makita M. Pseudoelastic behaviour of TiNi shape memory alloy subjected to strain variations. Journal of Intelligent Material Systems and Structures, 1994, 5(5): 694–701
|
| [88] |
Tobushi H, Shimeno Y, Hachisuka T, Tanaka K. Influence of strain rate on superelastic properties of TiNi shape memory alloy. Mechanics of Materials, 1998, 30(2): 141–150
|
| [89] |
Ren W, Li H, Song G. A one-dimensional strain-rate-dependent constitutive model for superelastic shape memory alloys. Smart Materials and Structures, 2007, 16(1): 191–197
|
| [90] |
Iadicola M A, Shaw J A. Rate and thermal sensitivities of unstable transformation behavior in a shape memory alloy. International Journal of Plasticity, 2004, 20(4–5): 577–605
|
| [91] |
Favier D, Louche H, Schlosser P, Orgéas L, Vacher P, Debove L. Homogeneous and heterogeneous deformation mechanisms in an austenitic polycrystalline Ti–50.8 at.% Ni thin tube under tension. Investigation via temperature and strain fields measurements. Acta Materialia, 2007, 55(16): 5310–5322
|
| [92] |
Hallai J F, Kyriakides S. Underlying material response for Lüders-like instabilities. International Journal of Plasticity, 2013, 47: 1–12
|
| [93] |
Reedlunn B, Churchill C B, Nelson E E, Shaw J A, Daly S H. Tension, compression, and bending of superelastic shape memory alloy tubes. Journal of the Mechanics and Physics of Solids, 2014, 63: 506–537
|
| [94] |
de Oliveira Ramos A D, de Araújo C J, de Oliveira H M R, Macêdo G A, de Lima A G B. An experimental investigation of the superelastic fatigue of NiTi SMA wires. Journal of the Brazilian Society of Mechanical Sciences and Engineering, 2018, 40(4): 206
|
| [95] |
Shi F, Ozbulut O E, Li Z, Wu Z, Ren F, Zhou Y. Effects of ambient temperature on cyclic response and functional fatigue of shape memory alloy cables. Journal of Building Engineering, 2022, 52: 104340
|
| [96] |
Davarnia D, Cheng S, van Engelen N. Effect of training on the cyclic behaviour of SMA wire. Smart Materials and Structures, 2023, 32(8): 085013
|
| [97] |
Zhang Y, Chai X, Ju X, You Y, Zhang S, Zheng L, Moumni Z, Zhu J, Zhang W. Concentration of transformation-induced plasticity in pseudoelastic NiTi shape memory alloys: Insight from austenite–martensite interface instability. International Journal of Plasticity, 2023, 160: 103481
|
| [98] |
Gao P, Li R, Liu Y, Chen G, Zhu M, Jian Y, Wu Z, Lu X, Ren Y, Li C. In-situ synchrotron diffraction study of the localized phase transformation and deformation behavior in NiTi SMA. Materials Science and Engineering A, 2021, 805: 140560
|
| [99] |
Brinson L, Schmidt I, Lammering R. Stress-induced transformation behavior of a polycrystalline NiTi shape memory alloy: Micro and macromechanical investigations via in situ optical microscopy. Journal of the Mechanics and Physics of Solids, 2004, 52(7): 1549–1571
|
| [100] |
Pieczyska E A, Staszczak M, Dunić V, Slavković R, Tobushi H, Takeda K. Development of stress-induced martensitic transformation in TiNi shape memory alloy. Journal of Materials Engineering and Performance, 2014, 23(7): 2505–2514
|
| [101] |
Sun Q P, He Y J. A multiscale continuum model of the grain-size dependence of the stress hysteresis in shape memory alloy polycrystals. International Journal of Solids and Structures, 2008, 45(13): 3868–3896
|
| [102] |
Stupkiewicz S, Rezaee-Hajidehi M, Petryk H. Multiscale analysis of the effect of interfacial energy on non-monotonic stress–strain response in shape memory alloys. International Journal of Solids and Structures, 2021, 221: 77–91
|
| [103] |
Norfleet D M, Sarosi P M, Manchiraju S, Wagner M F X, Uchic M D, Anderson P M, Mills M J. Transformation-induced plasticity during pseudoelastic deformation in Ni–Ti microcrystals. Acta Materialia, 2009, 57(12): 3549–3561
|
| [104] |
Zhu X, Lei Y, Wan H, Li S, Dui G. Constitutive modeling of porosity and grain size effects on superelasticity of porous nanocrystalline NiTi shape memory alloy. Acta Mechanica, 2023, 234(12): 6499–6513
|
| [105] |
Xi S, Su Y. A phase field study of the grain-size effect on the thermomechanical behavior of polycrystalline NiTi thin films. Acta Mechanica, 2021, 232(11): 4545–4566
|
| [106] |
XiaMLiuPSunQ. Grain Size Effects on Young’s Modulus and Hardness of Nanocrystalline NiTi Shape Memory Alloy. Cham: Springer, 2017, 203–210
|
| [107] |
Sun Q, Aslan A, Li M, Chen M X. Effects of grain size on phase transition behavior of nanocrystalline shape memory alloys. Science China Technological Sciences, 2014, 57(4): 671–679
|
| [108] |
Yin H, He Y, Moumni Z, Sun Q. Effects of grain size on tensile fatigue life of nanostructured NiTi shape memory alloy. International Journal of Fatigue, 2016, 88: 166–177
|
| [109] |
Chen J, Yin H, Sun Q. Effects of grain size on fatigue crack growth behaviors of nanocrystalline superelastic NiTi shape memory alloys. Acta Materialia, 2020, 195: 141–150
|
| [110] |
Tanaka K, Kobayashi S, Sato Y. Thermomechanics of transformation pseudoelasticity and shape memory effect in alloys. International Journal of Plasticity, 1986, 2(1): 59–72
|
| [111] |
Zhang Y, You Y, Moumni Z, Anlas G, Zhu J, Zhang W. Experimental and theoretical investigation of the frequency effect on low cycle fatigue of shape memory alloys. International Journal of Plasticity, 2017, 90: 1–30
|
| [112] |
Shaw J A. Simulations of localized thermo-mechanical behavior in a NiTi shape memory alloy. International Journal of Plasticity, 2000, 16(5): 541–562
|
| [113] |
Sedlák P, Frost M, Benešová B, Ben Zineb T, Šittner P. Thermomechanical model for NiTi-based shape memory alloys including R-phase and material anisotropy under multi-axial loadings. International Journal of Plasticity, 2012, 39: 132–151
|
| [114] |
Yin H, He Y, Sun Q. Effect of deformation frequency on temperature and stress oscillations in cyclic phase transition of NiTi shape memory alloy. Journal of the Mechanics and Physics of Solids, 2014, 67: 100–128
|
| [115] |
Dayananda G N, Rao M S. Effect of strain rate on properties of superelastic NiTi thin wires. Materials Science and Engineering A, 2008, 486(1–2): 96–103
|
| [116] |
Azadi B, Rajapakse R K N D, Maijer D M. One-dimensional thermomechanical model for dynamic pseudoelastic response of shape memory alloys. Smart Materials and Structures, 2006, 15(4): 996–1008
|
| [117] |
Rajoriya S, Mishra S S. Size, length, temperature and loading range effects on deformation response of NiTi SMA wire: An analytical study. Innovative Infrastructure Solutions, 2022, 7(3): 217
|
| [118] |
Wolons D, Gandhi F, Malovrh B. Experimental investigation of the pseudoelastic hysteresis damping characteristics of shape memory alloy wires. Journal of Intelligent Material Systems and Structures, 1998, 9(2): 116–126
|
| [119] |
Dolce M, Cardone D. Mechanical behaviour of shape memory alloys for seismic applications 2. Austenite NiTi wires subjected to tension. International Journal of Mechanical Sciences, 2001, 43(11): 2657–2677
|
| [120] |
Soul H, Isalgue A, Yawny A, Torra V, Lovey F C. Pseudoelastic fatigue of NiTi wires: Frequency and size effects on damping capacity. Smart Materials and Structures, 2010, 19(8): 085006
|
| [121] |
Wang B, Zhu S. Cyclic tension–compression behavior of superelastic shape memory alloy bars with buckling-restrained devices. Construction & Building Materials, 2018, 186: 103–113
|
| [122] |
YangZLiuJLinJ. Experimental Research on Inhibition of temperature to inverse martensitic phase transformation of NiTi Shape Memory Alloy. In: IOP Conference Series: Earth and Environmental Science. Bristol: IOP Publishing, 2020, 072057
|
| [123] |
Liu B, Li B, Wang S, Liu Y, Yang T, Zhou Y. A 1D strain-amplitude- and strain-rate-dependent model of super-elastic shape memory alloys for structural vibration control. Structures, 2020, 25: 426–435
|
| [124] |
Kaup A, Altay O, Klinkel S. Strain amplitude effects on the seismic performance of dampers utilizing shape memory alloy wires. Engineering Structures, 2021, 244: 112708
|
| [125] |
Yu C, Kang G, Kan Q, Zhu Y. Rate-dependent cyclic deformation of super-elastic NiTi shape memory alloy: Thermo-mechanical coupled and physical mechanism-based constitutive model. International Journal of Plasticity, 2015, 72: 60–90
|
| [126] |
Strnadel B, Ohashi S, Ohtsuka H, Miyazaki S, Ishihara T. Effect of mechanical cycling on the pseudoelasticity characteristics of Ti-Ni and Ti-Ni-Cu alloys. Materials Science and Engineering A, 1995, 203(1–2): 187–196
|
| [127] |
Xu X, Cheng G, Zheng J. Tests on pretrained superelastic NiTi shape memory alloy rods: Towards application in self-centering link beams. Advances in Civil Engineering, 2018, 1: 1–13
|
| [128] |
ZareieSZabihollahA. Hysteresis Behavior of Pre-Strained Shape Memory Alloy Wires Subject to Cyclic Loadings: An Experimental Investigation. London: IntechOpen, 2020
|
| [129] |
WhittakerA S. Structural Control of Buildings Response Using Shape-Memory Alloys. 1995
|
| [130] |
Choi E, Jeon J S, Kim W J, Kang J W. Investigation of MRS and SMA dampers effects on bridge seismic resistance employing analytical models. International Journal of Steel Structures, 2018, 18(4): 1325–1335
|
| [131] |
Ge J, Saiidi M S, Varela S. Computational studies on the seismic response of the State Route 99 bridge in Seattle with SMA/ECC plastic hinges. Frontiers of Structural and Civil Engineering, 2019, 13(1): 149–164
|
| [132] |
Kang G, Kan Q, Yu C, Song D, Liu Y. Whole-life transformation ratchetting and fatigue of super-elastic NiTi Alloy under uniaxial stress-controlled cyclic loading. Materials Science and Engineering A, 2012, 535: 228–234
|
| [133] |
Ammar O, Haddar N, Dieng L. Experimental investigation of the pseudoelastic behaviour of NiTi wires under strain- and stress-controlled cyclic tensile loadings. Intermetallics, 2017, 81: 52–61
|
| [134] |
Gu X, Zhang Y, You Y, Ju X, Zhu J, Moumni Z, Zhang W. Evolution of transformation characteristics of shape memory alloys during cyclic loading: Transformation temperature hysteresis and residual martensite. Smart Materials and Structures, 2020, 29(9): 095011
|
| [135] |
Nayan N, Buravalla V, Ramamurty U. Effect of mechanical cycling on the stress–strain response of a martensitic Nitinol shape memory alloy. Materials Science and Engineering A, 2009, 525(1–2): 60–67
|
| [136] |
Roy D, Buravalla V, Mangalgiri P D, Allegavi S, Ramamurty U. Mechanical characterization of NiTi SMA wires using a dynamic mechanical analyzer. Materials Science and Engineering A, 2008, 494(1–2): 429–435
|
| [137] |
Wang X, Xu B, Yue Z. Phase transformation behavior of pseudoelastic NiTi shape memory alloys under large strain. Journal of Alloys and Compounds, 2008, 463(1–2): 417–422
|
| [138] |
Frenzel J. On the importance of structural and functional fatigue in shape memory technology. Shape Memory and Superelasticity, 2020, 6(2): 213–222
|
| [139] |
Eggeler G, Hornbogen E, Yawny A, Heckmann A, Wagner M. Structural and functional fatigue of NiTi shape memory alloys. Materials Science and Engineering A, 2004, 378(1–2): 24–33
|
| [140] |
Kang G, Song D. Review on structural fatigue of NiTi shape memory alloys: Pure mechanical and thermo-mechanical ones. Theoretical and Applied Mechanics Letters, 2015, 5(6): 245–254
|
| [141] |
Hua P, Chu K, Ren F, Sun Q. Cyclic phase transformation behavior of nanocrystalline NiTi at microscale. Acta Materialia, 2020, 185: 507–517
|
| [142] |
Zhang Y, Moumni Z, Zhu J, Zhang W. Effect of the amplitude of the training stress on the fatigue lifetime of NiTi shape memory alloys. Scripta Materialia, 2018, 149: 66–69
|
| [143] |
Miyazaki S, Imai T, Igo Y, Otsuka K. Effect of cyclic deformation on the pseudoelasticity characteristic of Ti-Ni alloys. Metallurgical transactions A, 1986, 17: 115–120
|
| [144] |
McCormick J, Barbero L, DesRoches R. Effect of mechanical training on the properties of superelastic shape memory alloys for seismic applications. Proceedings of the Society for Photo-Instrumentation Engineers, 2005, 5764: 430–439
|
| [145] |
Zhang Y, Camilleri J A, Zhu S. Mechanical properties of superelastic Cu–Al–Be wires at cold temperatures for the seismic protection of bridges. Smart Materials and Structures, 2008, 17(2): 025008
|
| [146] |
Chen P, Cai X, Liu Y, Wang Z, Jin M, Jin X. Combined effects of grain size and training on fatigue resistance of nanocrystalline NiTi shape memory alloy wires. International Journal of Fatigue, 2023, 168: 107461
|
| [147] |
Sadiq H, Wong M B, Al-Mahaidi R, Zhao X L. The effects of heat treatment on the recovery stresses of shape memory alloys. Smart Materials and Structures, 2010, 19(3): 035021
|
RIGHTS & PERMISSIONS
Higher Education Press
