Applying Full-Field Measurement Techniques for the Thermomechanical Characterization of Shape Memory Alloys: A Review and Classification

1.

Pierron F, Grédiac M (2021) Towards Material Testing 2.0. A review of test design for identification of constitutive parameters from full-field measurements. Strain 57:e12370

2.

Roux S, Besnard G, Hild F (2006) Finite-element displacement fields analysis from digital images: application to Portevin-Le Châtelier bands. Exp Mech 46:789–803

3.

Pan B, Qian K, Xie H, Asundi A (2009) Two-dimensional digital image correlation for in-plane displacement and strain measurement: a review. Meas Sci Technol 20:062001

4.

Wittevrongel L, Lava P, Lomov SV, Debruyne D (2015) A self adaptive global digital image correlation algorithm. Exp Mech 55:361–378

5.

Kammers A, Daly S (2011) Small-scale patterning methods for digital image correlation under scanning electron microscopy. Meas Sci Technol 22:125501

6.

Kammers A, Daly S (2013) Digital image correlation under scanning electron microscopy: methodology and validation. Exp Mech 53:1743–1761

7.

Kammers A, Daly S (2013) Self-assembled nanoparticle surface patterning for improved digital image correlation in a scanning electron microscope. Exp Mech 53:1333–1341

8.

Weidner A, Biermann H (2021) Review on strain localization phenomena studied by high-resolution digital image correlation. Adv Eng Mater 23:2001409

9.

Grédiac M, Blaysat B, Sur F (2017) A critical comparison of some metrological parameters characterizing local Digital Image Correlation and Grid Method. Exp Mech 57:871–903

10.

Grédiac M, Sur F, Blaysat B (2020) Comparing several spectral methods used to extract displacement and strain fields from checkerboard images. Opt Lasers Eng 127:105984

11.

Reu PL, Blaysat B, Ando E, Bhattacharya K, Couture C, Couty V, Deb D, Fayad SS, Iadicola MA, Jaminion S, Klein M, Landauer AK, Lava P, Liu M, Luan LK, Olufsen SN, Réthoré J, Roubin E, Seidl DT, Siebert T, Stamati O, Toussaint E, Turner D, Vemulapati CSR, Weikert T, Witz JF, Witzel O, Yang J (2022) DIC challenge 2.0: developing images and guidelines for evaluating accuracy and resolution of 2D analyses. Focus on the metrological efficiency indicator. Exp Mech (accepted, in press). https://doi.org/10.1007/s11340-021-00806-6

12.

Sutton M, Orteu J, Schreier H (2009) Image correlation for shape, motion and deformation measurements: basic concepts, theory and applications. Springer, New York

13.

Bomarito G, Hochhalter J, Ruggles T, Cannon A (2017) Increasing accuracy and precision of digital image correlation through pattern optimization. Opt Lasers Eng 91:73–85

14.

Fayad S, Seidl D, Reu P (2020) Spatial DIC errors due to pattern-induced bias and grey level discretization. Exp Mech 60:249–263

15.

Sur F, Blaysat B, Grédiac M (2021) On biases in displacement estimation for image registration, with a focus on photomechanics. J Math Imaging Vision 63:777–806. https://doi.org/10.1007/S10851-021-01032-4

16.

Grédiac M, Blaysat B, Sur F (2019) Extracting displacement and strain fields from checker-board images with the localized spectrum analysis. Exp Mech 59:207–218

17.

Grédiac M, Blaysat B, Sur F (2020) On the optimal pattern for displacement field measurement: random speckle and DIC, or checkerboard and LSA? Exp Mech 60:509–534

18.

Grédiac M, Sur F, Blaysat B (2016) Removing quasi-periodic noise in strain maps by filtering in the Fourier domain. Exp Tech 40:959–971

19.

Mirmohammad H, Kingstedt O (2021) Theoretical considerations for transitioning the grid method technique to the microscale. Exp Mech 61:753–770

20.

Piro J, Grédiac M (2004) Producing and transferring low-spatial-frequency grids for measuring displacement fields with moiré and grid methods. Exp Tech 28:23–26

21.

Surrel Y (2003) Images optiques; mesures 2D et 3D. Conservatoire National des Arts et Métiers, Paris

22.

Post D, Han B, Ifju P (1994) High sensitivity moiré. Experimental analysis for mechanical and materials. Springer, New York

23.

Surrel Y (2005) Les techniques optiques de mesure de champ: essai de classification. Instr Mes Metrol 5:1–2

24.

Jacquot P (2008) Speckle interferometry: a review of the principal methods in use for experimental mechanics applications. Strain 44:57–69

25.

Asundi A (1989) Moiré interferometry for deformation measurement. Opt Lasers Eng 11:281–292

26.

Vollmer M, Mollman K (2018) Infrared thermal imaging: fundamentals, research and applications, 2nd edn. Wiley, Hoboken

27.

Batsale J, Chrysochoos A, Pron H, Wattrisse B (2012) Thermographic analysis of material behavior. In: Grédiac M, Hild F (eds) Full-field measurements and identification in solid mechanics, vol 16. Wiley, Hoboken, pp 439–468

28.

Jing Y, Laurent F, Stéphane A, Alain N (2016) A numerical study of heat source reconstruction for the advection diffusion operator: a conjugate gradient method stabilized with SVD. Int J Therm Sci 104:68–85

29.

Chrysochoos A, Louche H (2000) An infrared image processing to analyse the calorific effects accompanying strain localisation. Int J Eng Sci 38:1759–1788

30.

Poulsen H, Lauridsen SNE, Schmidt S, Suter R, Lienert U, Margulies L, Lorentzen T, Jensen D (2001) Three-dimensional maps of grain boundaries and the stress state of individual grains in polycrystals and powders. J Appl Crystallogr 34:751–756

31.

Korsunsky A, Vorster W, Zhang S, Dini D, Latham D, Golshan M, Liu J, Kyriakoglou Y, Walsh M (2006) The principle of strain reconstruction tomography: determination of quench strain distribution from diffraction measurements. Acta Mater 54:2101–2108

32.

Hayashi Y, Hirose Y, Seno Y (2015) Polycrystal orientation mapping using scanning three-dimensional X-ray diffraction microscopy. J Appl Crystallogr 48:1094–1101

33.

Hektor J, Hall S, Henningsson N, Engqvist J, Ristinmaa M, Lenrick F, Wright J (2019) Scanning 3DXRD measurement of grain growth, stress, and formation of Cu₆Sn₅ around a Tin Whisker during heat treatment. Materials 12:446

34.

Henningsson N, Hall S, Wright J, Hektor J (2020) Reconstructing intragranular strain fields in polycrystalline materials from scanning 3DXRD data. J Appl Crystallogr 53:314–325

35.

Sedmák P, Pilch J, Heller L, Kopeček J, Wright J, Sedlák P, Frost M, Šittner P (2016) Grain-resolved analysis of localized deformation in nickel-titanium wire under tensile load. Science 353:559–562

36.

Reedlunn B, Daly S, Hector L, Zavattieri P, Shaw J (2013) Tips and tricks for characterizing shape memory wire part 5: full-field strain measurement by digital image correlation. Exp Tech 37:62–78

37.

Jury A, Balandraud X, Heller L, Šittner P, Karlik M (2021) Reconstruction of heat sources induced in superelastically loaded Ni–Ti wire by localized deformation processes. Exp Mech 61:349–366

38.

Reedlunn B, Churchill CB, Nelson EE, Shaw JA, Daly SH (2014) Tension, compression, and bending of superelastic shape memory alloy tubes. J Mech Phys Solids 63:506–537

39.

Xiao Y, Zeng P, Lei L, Du H (2015) Local mechanical response of superelastic NiTi shape-memory alloy under uniaxial loading. Shap Mem Superelasticity 1:468–478

40.

Delpueyo D, Grédiac M, Balandraud X, Badulescu C (2012) Investigation of martensitic microstructures in a monocrystalline Cu–Al–Be shape memory alloy with the grid method and infrared thermography. Mech Mater 45:34–51

41.

Polatidis E, Smid M, Kubena I, Hsu W, Laplanche G, Van Swygenhoven H (2020) Deformation mechanisms in a superelastic NiTi alloy: an in-situ high resolution digital image correlation study. Mater Des 191:108622

42.

Zhang X, Xu T, Sun Q, Tong P (1997) On the full-field deformation of single crystal CuAlNi shape memory alloys stress-induced beta(1)->gamma’(1) martensitic transformation. J Phys IV 7:555–560

43.

Louche H, Schlosser P, Favier D, Orgéas L (2012) Heat source processing for localized deformation with non-constant thermal conductivity. application to superelastic tensile tests of NiTi shape memory alloys. Exp Mech 52:1313–1328

44.

Murasawa G, Yoneyama S, Tohgo K, Takashi M (2004) Distribution of unique performances for shape memory alloy composite. In: Lee S, Yoon D, Lee J, Lee S (eds) Advances in nondestructive evaluation, PT 1–3. Key engineering materials, vol 270–273. Trans Tech Publications Ltd, Zurich, pp 2172–2178

45.

Murasawa G (2005) Analytical model for predicting internal stress and deformation of shape memory alloy composite. In: Armstrong W (ed) Smart structures and materials 2005: active materials: behavior and mechanics, vol 5761. International Society for Optics and Photonics, Bellingham, pp 395–405

46.

Shaw J, Kyriakides S (1997) On the nucleation and propagation of phase transformation fronts in a NiTi alloy. Acta Mater 45:683–700

47.

Tobushi H, Nakahara T, Shimeno Y, Hashimoto T (1999) Low-cycle fatigue of TiNi shape memory alloy and formulation of fatigue life. ASME J Eng Mater Technol 122:186–191

48.

Balandraud X, Chrysochoos A, Leclercq S, Peyroux R (2001) Influence of the thermomechanical coupling on the propagation of a phase change front. C R Acad Sci—Ser IIb—Mech 329:621–626

49.

Helm D, Haupt P (2001) Thermomechanical behavior of shape memory alloys. In: Lynch C (ed) Smart structures and materials 2001: active materials: behavior and mechanics, vol 4333. International Society for Optics and Photonics, Bellingham, pp 302–313

50.

Iadicola M, Shaw JA (2002) The effect of uniaxial cyclic deformation on the evolution of phase transformation fronts in pseudoelastic NiTi wire. J Intell Mater Syst Struct 13:143–155

51.

Gadaj S, Nowacki W, Pieczyska E (2002) Temperature evolution in deformed shape memory alloy. Infrared Phys Technol 43:151–155

52.

Iadicola M, Shaw J (2002) An experimental setup for measuring unstable thermo-mechanical behavior of shape memory alloy wire. J Intell Mater Syst Struct 13:157–166

53.

Lu R, Fang R (2002) Compressive response of CuAlNi single crystal. In: Shen G, Cha S, Chiang F, Mercer C (eds) Optical technology and image processing for fluids and solids diagnostics 2002, vol 5058. International Society for Optics and Photonics, Bellingham, pp 633–637

54.

Ng Y, Song C, McLean D, Shimi SM, Frank TG, Cuschieri A, Campbell PA (2003) Optimized deployment of heat-activated surgical staples using thermography. Appl Phys Lett 83:1884–1886

55.

Iadicola M, Shaw J (2004) Rate and thermal sensitivities of unstable transformation behavior in a shape memory alloy. Int J Plast 20:577–605

56.

Turner T, Buehrle R, Cano R, Flemings G (2004) Design, fabrication, and testing of SMA enabled adaptive chevrons for jet noise reduction. In: Flatau A (ed) Smart structures and materials 2004: smart structures and integrated systems, vol 5390. International Society for Optics and Photonics, Bellingham, pp 297–308

57.

Gadaj S, Nowacki W, Pieczyska E, Tobushi H (2005) Temperature measurement as a new technique applied to the phase transformation study in a TiNi shape memory alloy subjected to tension. Arch Metall Mater 50:661–674

58.

Chrysochoos A, Licht C, Peyroux R (2005) Propagation of phase change front in monocrys-talline SMA. In: Fremond M, Marceri F (eds) Mechanical modelling and computational issues in civil engineering, vol 23. Springer, Berlin, Heidelberg, pp 369–377

59.

Chang B, Shaw J, Iadicola M (2006) Thermodynamics of shape memory alloy wire: modeling, experiments, and application. Continuum Mech Thermodyn 18:83–118

60.

Pieczyska EA, Gadaj SP, Nowacki WK, Tobushi H (2006) Phase-transformation fronts evolution for stress- and strain-controlled tension tests in TiNi shape memory alloy. Exp Mech 46:531–542

61.

Pieczyska EA, Tobushi H, Gadaj S, Nowacki W (2006) Superelastic deformation behaviors based on phase transformation bands in TiNi shape memory alloy. Mater Trans 47:670–676

62.

Vieille B, Michel J, Boubakar M, Lexcellent C (2007) Validation of a 3D numerical model of shape memory alloys pseudoelasticity through tensile and bulging tests on CuAlBe sheets. Int J Mech Sci 49:280–297

63.

Seiner H, Landa M, Sedlák P (2007) Propagation of an austenite-martensite interface in a thermal gradient. Proc Est Acad Sci Phys Math 56:218–225

64.

Favier D, Louche H, Schlosser P, Orgéas L, Vacher P, Debove L (2007) Homogeneous and heterogeneous deformation mechanisms in an austenitic polycrystalline Ti-50.8at.% Ni thin tube under tension. Investigation via temperature and strain fields measurements. Acta Mater 55:5310–5322

65.

Schlosser P, Louche H, Favier D, Orgéas L (2007) Image processing to estimate the heat sources related to phase transformations during tensile test of NiTi tubes. Strain 43:260–271

66.

Iadicola MA, Shaw JA (2007) An experimental method to measure initiation events during unstable stress-induced martensitic transformation in a shape memory alloy wire. Smart Mater Struct 16:S155–S169

67.

Gollerthan S, Young M, Neuking K, Ramamurty U, Eggeler G (2009) Direct physical evidence for the back-transformation of stress-induced martensite in the vicinity of cracks in pseudoelastic NiTi shape memory alloys. Acta Mater 57:5892–5897

68.

Churchill CB, Shaw JA, Iadicola MA (2009) Tips and tricks for characterizing shape memory alloy wire: Part 3-localization and propagation phenomena. Exp Tech 33:70–78

69.

Grolleau V, Louche H, Penin A, Chauvelon P, Rio G, Liu Y, Favier D (2009) Bulge tests on ferroelastic and superelastic NiTi sheets with full field thermal and 3D-kinematical measurements: experiments and modelling. In: Sittner P, Paidar V, Heller L, Seiner H (eds) ESOMAT 2009–8th European symposium on martensitic transformations. EDP Sciences, Les Ulis

70.

Schlosser P, Favier D, Louche H, Orgéas L, Liu Y (2009) From the thermal and kinematical full-field measurements to the analysis of deformation mechanisms of NiTi SMAs. In: Sittner P, Paidar V, Heller L, Seiner H (eds) ESOMAT 2009–8th European symposium on martensitic transformations. EDP Sciences, Les Ulis

71.

Pieczyska E, Gadaj S, Luckner J, Nowacki W, Tobushi H (2009) Martensite and reverse transformation during complete cycle of simple shear of NiTi shape memory alloy. Strain 45:93–100

72.

Vigneron S, Chrysochoos A, Peyroux R, Wattrisse B (2009) Analyse énergétique de la localisation du changement de phase dans un AMF monocristallin. Congrès Français de Mécanique, 24–28 August 2009, Marseille, France

73.

Churchill CB, Shaw JA, Iadicola MA (2010) Tips and tricks for characterizing shape memory alloy wire: Part 4—thermo-mechanical coupling. Exp Tech 34:63–80

74.

Pieczyska E, Tobushi H (2010) Infrared imaging of TiNi shape memory alloy subjected to deformation at various temperatures. In: Bremand F (ed) ICEM 14: 14th international conference on experimental mechanics, vol 6. EDP Sciences, Les Ulis

75.

Saletti D, Pattofatto S, Zhao H (2010) Evolution of the martensitic transformation in shape memory alloys under high strain rates. In: Bremand F (ed) ICEM 14: 14th international conference on experimental mechanics, vol 6. EDP Sciences, Les Ulis

76.

Kim K, Juggernauth K, Daly S (2010) Stress-induced martensitic phase transformation in nitinol under hard cyclic loading. ASME 2010 conference on smart materials, adaptive structures and intelligent systems. Vol. 1. Smart materials, adaptive structures and intelligent systems. AMSE, Orlando, pp 1–7

77.

Delpueyo D, Balandraud X, Grédiac M, Fillit R (2010) Thermoelastic analysis of a copper-based monocristalline shape-memory alloy. In: Bremand F (ed) ICEM 14: 14th international conference on experimental mechanics, vol 6. EDP Sciences, Les Ulis

78.

Zhang X, Feng P, He Y, Yu T, Sun Q (2010) Experimental study on rate dependence of macroscopic domain and stress hysteresis in NiTi shape memory alloy strips. Int J Mech Sci 52:1660–1670

79.

Maynadier A, Poncelet M, Lavernhe-Taillard K, Roux S (2010) One-shot thermal and kinematic field measurements: infra-red image correlation. In: Bremand F (ed) ICEM 14: 14th international conference on experimental mechanics, vol 6. EDP Sciences, Les Ulis

80.

Pieczyska E (2010) Activity of stress-induced martensite transformation in TiNi shape memory alloy studied by infrared technique. J Mod Opt 57:1700–1707

81.

Vives E, Burrows S, Edwards RS, Dixon S, Mañosa L, Planes A, Romero R (2011) Temperature contour maps at the strain-induced martensitic transition of a Cu–Zn–Al shape—memory single crystal. Appl Phys Lett 98:011902

82.

Kim K, Daly S (2011) Martensite strain memory in the shape memory alloy nickel-titanium under mechanical cycling. Exp Mech 51:641–652

83.

Pieczyska E, Dutkiewiczf J, Masdeu F, Luckner J, Maciak R (2011) Investigation of thermomechanical properties of ferromagnetic NiFeGa shape memory alloy subjected to pseudoelastic compression test. Arch Metall Mater 56:401–408

84.

Delpueyo D, Balandraud X, Grédiac M (2011) Applying infrared thermography to analyse martensitic microstructures in a Cu–Al–Be shape-memory alloy subjected to a cyclic loading. Mater Sci Eng A 528:8249–8258

85.

Takeda K, Tobushi H, Miyamoto K, Pieczyska EA (2012) Superelastic deformation of TiNi shape memory alloy subjected to various subloop loadings. Mater Trans 53:217–223

86.

Pieczyska EA, Tobushi H, Takeda K, Stró D (2012) Martensite transformation bands studied in TiNi shape memory alloy by infrared and acoustic emission techniques. Kovove Mater 50:309–318

87.

Dunand-Chatellet C, Moumni Z (2012) Coupling Infrared thermography and acoustic emis sion measurement to quantify the shakedown state of shape memory alloys. In: Tonkovic Z, Aliabadi M (eds) Advances in fracture and damage mechanics X. Vol 488–489. Key engineering materials. Trans Tech Publications Ltd, Zurich, pp 146–149

88.

Bechtold C, Chluba C, De Miranda R, Quandt E (2012) High cyclic stability of the elastocaloric effect in sputtered TiNiCu shape memory films. Appl Phys Lett 101:091903

89.

Yan Y, Yin H, Sun QP, Huo Y (2012) Rate dependence of temperature fields and energy dissipations in non-static pseudoelasticity. Continuum Mech Thermodyn 24:675–695

90.

Pieczyska E, Tobushi H, Kulasinski K, Takeda K (2012) Thermomechanical coupling effects in TiNi SMA subjected to compression. Mater Trans 53:1905–1909

91.

Maynadier A, Poncelet M, Lavernhe-Taillard K, Roux S (2012) One-shot measurement of thermal and kinematic fields: infrared image correlation (IRIC). Exp Mech 52:241–255

92.

Cui J, Wu Y, Muehlbauer J, Hwang Y, Radermacherand R, Fackler S, Wuttig M, Takeuchi I (2012) Demonstration of high efficiency elastocaloric cooling with large delta T using NiTi wires. Appl Phys Lett 101:073904

93.

Reedlunn B, Daly S, Shaw J (2013) Superelastic shape memory alloy cables: Part I—isothermal tension experiments. Int J Solids Struct 50:3009–3026

94.

Reedlunn B, Daly S, Shaw J (2013) Superelastic shape memory alloy cables: Part II–sub-component isothermal responses. Int J Solids Struct 50:3027–3044

95.

Pieczyska E, Tobushi H, Kulasinski K (2013) Development of transformation bands in TiNi SMA for various stress and strain rates studied by a fast and sensitive infrared camera. Smart Mater Struct 22:035007

96.

Krevet B, Pinneker V, Rhode M, Bechthold C, Quandt E, Kohl M (2013) Evolution of temperature profiles during stress-induced transformation in NiTi thin films. In: Prokoshkin S, Resnina N (eds) European symposium on martensitic transformations. Vol. 738–739. Materials science forum. Trans Tech Publications Ltd, Zurich, pp 287–292

97.

Ossmer H, Chluba C, Krevet B, Quandt E, Rohde M, Kohl M (2013) Elastocaloric cooling using shape memory alloy films. 13th international conference on micro and nanotechnology for power generation and energy conversion applications (POWERMEMS 2013). Vol. 476. Journal of physics conference series. IOP Publishing Ltd, Bristol

98.

Du H, Zeng P, Zhao J, Lei L, Fang G, Qu T (2013) In situ multi-fields investigation on instability and transformation localization of martensitic phase transformation in NiTi alloys. Acta Metall Sin 49:17–25

99.

Saletti D, Pattofatto S, Zhao H (2013) Measurement of phase transformation properties under moderate impact tensile loading in a NiTi alloy. Mech Mater 65:1–11

100.

Cornell S, Hartl D, Lagoudas D (2014) Experimental validation of a shape memory alloy constitutive model by heterogeneous thermal loading using infrared thermography and digital image correlation. Proceedings of the ASME conference on smart materials adaptative structures and intelligent systems, vol 2. ASME, New York

101.

Yin H, He Y, Sun Q (2014) Effect of deformation frequency on temperature and stress oscillations in cyclic phase transition of NiTi shape memory alloy. J Mech Phys Solids 67:100–128

102.

Ossmer H, Lambrecht F, Gültig M, Chluba C, Quandt E, Kohl M (2014) Evolution of temperature profiles in TiNi films for elastocaloric cooling. Acta Mater 81:9–20

103.

Depriester D, Maynadier A, Lavernhe-Taillard K, Hubert O (2014) Thermomechanical modelling of a NiTi SMA sample submitted to displacement-controlled tensile test. Int J Solids Struct 51:1901–1922

104.

Ahadi A, Sun Q (2014) Effects of grain size on the rate-dependent thermomechanical responses of nanostructured superelastic NiTi. ACTA Mater 76:186–197

105.

Pieczyska E, Kowalczyk-Gajewska K, Maj M, Staszczak M, Tobushi H (2014) Thermo-mechanical Investigation of TiNi shape memory alloy and PU shape memory polymer subjected to cyclic loading. In: Guagliano M, Vergani L (eds) XVII international colloquium on mechanical fatigue of metals (ICMFM17) Vol. 74. Procedia engineering. Elsevier, Amsterdam, pp 287–292

106.

Daghash S, Ozbulut O, Sherif M (2014) Shape memory alloy cables for civil infrastructure systems. Proceedings of the ASME conference on smart materials adaptive structures and intelligent systems, vol 1. ASME, New York

107.

Maletta C, Bruno L, Corigliano P, Crupi V, Guglielmino E (2014) Crack-tip thermal and mechanical hysteresis in shape memory alloys under fatigue loading. Mater Sci Eng A 616:281–287

108.

Pelegrina J, Yawny A, Olbricht J, Eggeler G (2015) Transformation activity in ultrafine grained pseudoelastic NiTi wires during small amplitude loading/unloading experiments. J Alloys Compd 651:655–665

109.

Pieczyska EA (2015) Mechanical behavior and infrared imaging of ferromagnetic NiFeGaCo SMA single crystal subjected to subsequent compression cycles. Arch Metall Mater 50:585–590

110.

Delobelle V, Favier D, Louche H, Connesson N (2015) Determination of local thermo-physical properties and heat of transition from thermal fields measurement during drop calorimetric experiment. Exp Mech 55:711–723

111.

Pataky GJ, Ertekin E, Sehitoglu H (2015) Elastocaloric cooling potential of NiTi, Ni₂FeGa, and CoNiAl. Acta Mater 96:420–427

112.

Xiao Y, Zeng P, Lei L, Du H (2015) Experimental investigation on rate dependence of thermomechanical response in superelastic NiTi shape memory alloy. J Mater Eng Perform 24:3755–3760

113.

Alarcon E, Heller L, Chirani S, Sittner P, Saint-Sulpice L, Calloch S (2015) Phase transformations and fatigue of NiTi. In: Schryvers N, Van Humbeeck J (eds) ESOMAT 2015, 10th European symposium on martensitic transformations, vol 33. EDP Sciences, Les Ulis

114.

Ossmer H, Chluba C, Gueltig M, Quandt E, Kohl M (2015) Local evolution of the elastocaloric effect in TiNi-based films. Shap Mem Superelasticity 1:142–152

115.

Schmidt M, Schutze A, Seelecke S (2015) Scientific test setup for investigation of Shape memory alloy based elastocaloric cooling processes. Int J Refrig 54:88–97

116.

Ossmer H, Miyazaki S, Kohl M (2015) The elastocaloric effect in TiNi-based foils. Materials today-proceedings, vol 2. Elsevier Science BV, Amsterdam, pp 971–974

117.

Tusek J, Engelbrecht K, Eriksen D, Dall’Olio S, Tusek J, Pryds N (2016) A regenerative elastocaloric heat pump. Nat Energy 1:16134

118.

Michalak M, Krucin I (2016) A smart fabric with increased insulating properties. Text Res J 86:97–111

119.

Ozbulut O, Daghash S, Sherif M (2016) Shape memory alloy cables for structural applica tions. J Mater Civil Eng 28:04015176

120.

Schmidt M, Ullrich J, Wieczorek A, Frenzel J, Eggeler G, Schütze A, Seelecke S (2016) Experimental methods for investigation of shape memory based elastocaloric cooling processes and model validation. J Vis Exp 111:53626

121.

Kan Q, Yu C, Kang G, Li J, Yan W (2016) Experimental observations on rate-dependent cyclic deformation of super-elastic NiTi shape memory alloy. Mech Mater 97:48–58

122.

Xie X, Kan Q, Kang G, Li J, Qiu B, Yu C (2016) Observation on the transformation domains of super-elastic NiTi shape memory alloy and their evolutions during cyclic loading. Smart Mater Struct 25:045003

123.

Bechle NJ, Kyriakides S (2016) Evolution of phase transformation fronts and associated thermal effects in a NiTi tube under a biaxial stress state. Extrem Mech Lett 8:55–63

124.

Bruederlin F, Ossmer H, Wendler F, Miyazaki S, Kohl M (2017) SMA foil-based elastocaloric cooling: from material behavior to device engineering. J Phys D Appl Phys 50:424003

125.

Xia M, Sun Q (2017) Thermomechanical responses of nonlinear torsional vibration with NiTi shape memory alloy—alternative stable states and their jumps. J Mech Phys Solids 102:257–276

126.

Alarcon E, Heller L, Chirani SA, Sittner P, Kopecek J, Saint-Sulpice L, Calloch S (2017) Fatigue performance of superelastic NiTi near stress-induced martensitic transformation. Int J Fatigue 95:76–89

127.

You Y, Zhang Y, Moumni Z, Anlas G, Zhang W (2017) Effect of the thermomechanical coupling on fatigue crack propagation in NiTi shape memory alloys. Mater Sci Eng A 685:50–56

128.

Zhang Y, You Y, Moumni Z, Anlas G, Zhu J (2017) Experimental and theoretical investigation of the frequency effect on low cycle fatigue of shape memory alloys. Int J Plast 90:1–30

129.

Shen A, Zhao D, Sun W, Liu J, Li C (2017) Elastocaloric effect in a Co₅₀Ni₂₀Ga₃₀ single crystal. Scr Mater 127:1–5

130.

Zhao D, Liu J, Chen X, Sun W, Li Y, Zhang M, Shao Y, Zhang H, Yan A (2017) Giant caloric effect of low-hysteresis metamagnetic shape memory alloys with exceptional cyclic functionality. Acta Mater 133:217–223

131.

Sun W, Liu J, Zhao D, Zhang M (2017) Directional solidification and elastocaloric effect in a Ni₄₅Mn₄₄Sn₁₁ magnetic shape memory alloy. J Phys D Appl Phys 50:444001

132.

Pieczyska E, Kowalewski Z, Dunic V (2017) Stress relaxation effects in TiNi SMA during superelastic deformation: experiment and constitutive model. Shape Memory Superelasticity 3:392–402

133.

Xiao F, Chen H, Jin X, Nie Z, Kakeshita T, Fukuda T (2018) Stress-induced reverse martensitic transformation in a Ti-51Ni (at%) alloy aged under uniaxial stress. Sci Rep 8:6099

134.

Sharar D, Radice J, Warzoha R, Hanrahan B, Chang B (2018) First demonstration of a bending-mode elastocaloric cooling ‘Loop‘. Proceedings of the 17th IEEE Intersociety conference on thermal and thermomechanical phenomena in electronic systems (ITHERM 2018). IEEE, New York, pp 218–226

135.

Tusek J, Zerovnik A, Cebron M, Brojan M, Zuzek B, Engelbrecht K, Cadelli A (2018) Elastocaloric effect vs fatigue life: exploring the durability limits of Ni–Ti plates under pre-strain conditions for elastocaloric cooling. Acta Mater 150:295–307

136.

Yan K, Wei P, Ren F, He W, Sun Q (2019) Enhance fatigue resistance of nanocrystalline NiTi by laser shock peening. Shape Memory Superelasticity 5:436–443

137.

Fritsch E, Izadi M, Ghafoori E (2019) Development of nail-anchor strengthening system with iron-based shape memory alloy (Fe-SMA) strips. Constr Build Mater 229:117042

138.

Shen Y, Sun W, Wei Z, Shen Q, Zhang Y, Liu J (2019) Orientation dependent elastocaloric effect in directionally solidified Ni–Mn–Sn alloys. Scr Mater 163:14–18

139.

Wei Z, Sun W, Shen Q, Shen Y, Zhang Y, Liu E, Liu J (2019) Elastocaloric effect of all-d-metal Heusler NiMnTi(Co) magnetic shape memory alloys by digital image correlation and infrared thermography. Appl Phys Lett 114:101903

140.

Shariat BS, Bakhtiari S, Yang H, Liu Y (2019) Experimental and numerical data for transformation propagation in NiTi shape memory structures. Data Brief 27:104566

141.

Michaelis N, Welsch F, Kirsch SM, Seelecke S, Schütze A (2019) Resistance monitoring of shape memory material stabilization during elastocaloric training. Smart Mater Struct 28:105046

142.

Shariat BS, Bakhtiari S, Yang H, Liu Y (2019) Computational and experimental analyses of martensitic transformation propagation in shape memory alloys. J Alloys Compd 806:1522–1528

143.

Kabirifar P, Zerovnik A, Ahcin Z, Porenta L, Brojan M, Tusek J (2019) Elastocaloric cooling: state-of-the-art and future challenges in designing regenerative elastocaloric devices. Strojniski Vestnik—J Mech Eng 65:615–630. https://doi.org/10.5545/sv-jme.2019.6369CrossRef

144.

Sharar D, Donovan B, Warzoha R, Wilson A, Leff A, Hanrahan B (2019) Solid-state thermal energy storage using reversible martensitic transformations. Appl Phys Lett 114:143902

145.

You Y, Gu X, Zhang Y, Moumni Z, Anlas G, Zhang W (2019) Effect of thermomechanical coupling on stress-induced martensitic transformation around the crack tip of edge cracked shape memory alloy. Int J Fracture 216:123–133

146.

Jury A, Balandraud X, Heller L, Alarcon E, Karlik M (2020) One-dimensional heat source reconstruction applied to phase transforming superelastic Ni-Ti wire. In: Baldi A, Kramer S, Pierron F, Considine J, Bossuyt S, Hoefnagels J (eds) Residual stress, thermomechanics & infrared imaging and inverse problems, volume 6. conference proceedings of the society for experimental mechanics series. Springer, Cham, pp 33–40

147.

Shen Y, Wei Z, Sun W, Zhang Y, Liu E, Liu J (2020) Large elastocaloric effect in directionally solidified all-d-metal Heusler metamagnetic shape memory alloys. Acta Mater 188:677–685

148.

Asfaw A, Sherif M, Xing G, Ozbulut O (2020) Experimental investigation on buckling and post-buckling behavior of superelastic shape memory alloy bars. J Mater Eng Perform 29:3127–3140

149.

Wang J, Ren X, Xu Y, Zhang W, Zhu J, Li B (2020) Thermodynamic behavior of NiTi shape memory alloy against low-velocity impact: experiment and simulation. Int J Impact Eng 139:103532

150.

Furgiuele F, Magarò P, Maletta C, Sgambitterra E (2020) Functional and structural fatigue of pseudoelastic NiTi: global vs local thermo-mechanical response. Shape Memory Superelasticity 6:242–255

151.

Masoudi Moghaddam SA, Yarmohammad Tooski M, Jabbari M, Khorshidvand AR (2020) Experimental investigation of sandwich panels with hybrid composite face sheets and embedded shape memory alloy wires under low velocity impact. Polym Compos 41:4811–4829

152.

Yuan B, Qian M, Zhang X, Geng L (2020) Grain structure related inhomogeneous elastocaloric effects in Cu–Al–Mn shape memory microwires. Scr Mater 178:356–360

153.

Mutlu F, Anlaş G, Moumni Z (2020) Effect of loading rate on fracture mechanics of NiTi SMA. Int J Fracture 224:151–165

154.

Ianniciello L, Romanini M, Manosa L, Planes A, Engelbrecht K, Vives E (2020) Tracking the dynamics of power sources and sinks during the martensitic transformation of a Cu–Al–Ni single crystal. Appl Phys Lett 116:183901

155.

Nataf G, Romanini M, Vives E, Zuzek B, Planes A, Tusek J, Moya X (2020) Suppression of acoustic emission during superelastic tensile cycling of polycrystalline Ni_50.4Ti_49.6. Phys. Rev. Mater. 4:093604

156.

Li M, Chen M, Sun Q (2021) Nonlocal modeling and analysis of spatiotemporal patterns in non-isothermal phase transformation of NiTi strips. Int J Solids Struct 221:103–116

157.

Shariat BS, Bakhtiari S, Yang H, Liu Y (2021) Controlled initiation and propagation of stress-induced martensitic transformation in functionally graded NiTi. J Alloys Compd 851:156103

158.

Alarcon E, Heller L (2021) Deformation infrared calorimetry for materials characterization applied to study cyclic superelasticity in NiTi wires. Mater Des 199:109406

159.

Kilic U, Daghash S, Sherif M, Ozbulut O (2021) Tensile characterization of graphene nanoplatelet/shape memory alloy/epoxy composites using digital and thermal imaging. Polym Compos 42:1235–1244

160.

Jongchansitto P, Yachai T, Preechawuttipong I, Boufayed R, Balandraud X (2021) Concept of mechanocaloric granular material made from shape memory alloy. Energy 219:119656

161.

Lu N, Chen C (2021) Inhomogeneous martensitic transformation behavior and elastocaloric effect in a bicrystal Cu–Al–Mn shape memory alloy. Mater Sci Eng A 800:140386

162.

Sharar D, Radice J, Warzoha R, Hanrahan B, Smith A (2021) Low-force elastocaloric refrigeration via bending. Appl Phys Lett 118:184103

163.

Shastry V, Singh G, Ramamurty U (2021) On the fatigue life enhancement due to periodic healing of a NiTi shape memory alloy. Mater Sci Eng A 815:141272

164.

Calloch S, Bouvet C, Hild F, Doudard C, Lexcellent C (2002) Analysis of mechanical behavior and in-situ observations of Cu–Al–Be SMA under biaxial compressive tests by using DIC. X Wu, Y Qin, J Fang, J Ke (Eds) Third International Conference on Experimental Mechanics. Vol. 4537. Proceedings of the Society of Photo-Optical Instrumentation Engineers (SPIE). pp 83–86

165.

Moore CL, Bruck HA (2002) A fundamental investigation into large strain recovery of one-way shape memory alloy wires embedded in flexible polyurethanes. Smart Mater Struct 11:130–139

166.

Bruck HA, Moore CL, Valentine TL (2002) Repeatable bending actuation in polyurethanes using opposing embedded one-way shape memory alloy wires exhibiting large deformation recovery. Smart Mater Struct 11:305

167.

Umezaki E, Ichikawa T (2003) Measurement of deformation of epoxy resin plates with an embedded SMA wire using digital image correlation. Int J Mod Phys B 17:1750–1755

168.

Bruck HA, Moore CL, Valentine TM (2004) Bending actuation in polyurethanes with a symmetrically graded distribution of one-way shape memory alloy wires. Exp Mech 44:62–70

169.

Murasawa G, Yoneyama S, Sakuma T, Takashi M (2006) Influence of cyclic loading on inhomogeneous deformation behavior arising in NiTi shape memory alloy plate. Mater Trans 47:780–786

170.

Murasawa G, Yoneyama S (2006) Local strain distribution arising in shape memory alloy composite subjected to thermal loading. Mater Trans 47:766–771

171.

Shen L, He J, Su Y, Chu W, Qiao L (2006) In situ study of cracking for Ni₂MnGa ferro-magnetic shape memory alloy. Acta Metall Sin 42:810–814

172.

Dutta I, Pan D, Ma S, Majumdar B, Harris S (2006) Role of shape-memory alloy reinforcements on strain evolution in lead-free solder joints. Electron Mater 35:1902–1913

173.

Murasawa G, Yoneyama S, Sakuma T (2007) Nucleation, bifurcation and propagation of local deformation arising in NiTi shape memory alloy. Smart Mater Struct 16:160–167

174.

Daly S, Ravichandran G, Bhattacharya K (2007) Stress-induced martensitic phase transformation in thin sheets of Nitinol. Acta Mater 55:3593–3600

175.

Daly S, Miller A, Ravichandran G, Bhattacharya K (2007) An experimental investigation of crack initiation in thin sheets of nitinol. Acta Mater 55:6322–6330

176.

Hamilton R, Sehitoglu H, Aslantas K, Efstathiou C, Maier H (2008) Intermartensite strain evolution in NiMnGa single crystals. Acta Mater 56:2231–2236

177.

Efstathiou C, Sehitoglu H, Carroll J, Lambros J, Maier HJ (2008) Full-field strain evolution during intermartensitic transformations in single-crystal NiFeGa. Acta Mater 56:3791–3799

178.

Sánchez-Arévalo FM, Pulos G (2008) Use of digital image correlation to determine the mechanical behavior of materials. Mater Charact 59:1572–1579

179.

Efstathiou C, Sehitoglu H (2008) Local transformation strain measurements in precipitated NiTi single crystals. Scr Mater 59:1263–1266

180.

Daly S, Rittel D, Bhattacharya K, Ravichandran G (2009) Large deformation of nitinol under shear dominant loading. Exp Mech 49:225–233

181.

Merzouki T, Collard C, Bourgeois N, Zineb T, Meraghni F (2009) Coupling between experiment and numerical simulation of shape memory alloy multicrystal. In: Sittner P, Paidar V, Heller L, Seiner H (eds) ESOMAT 2009—8th European symposium on martensitic transformations. EDP Sciences, Les Ulis

182.

Murasawa G, Kitamura K, Yoneyama S, Miyazaki S, Miyata K, Nishioka A, Koda T (2009) Macroscopic stress-strain curve, local strain band behavior and the texture of NiTi thin sheets. Smart Mater Struct 18:055003

183.

Sánchez-Arévalo F, Garcia-Fernández T, Pulos G, Villagrán-Muniz M (2009) Use of digital speckle pattern correlation for strain measurements in a CuAlBe shape memory alloy. Mater Charact 60:775–782

184.

Schaefer A, Wagner M (2009) Strain mapping at propagating interfaces in pseudoelastic NiTi. In: Sittner P, Paidar V, Heller L, Seiner H (eds) ESOMAT 2009—8th European symposium on martensitic transformations. EDP Sciences, Les Ulis

185.

Bourgeois N, Meraghni F, Ben Zineb T (2010) Measurement of local strain heterogeneities in superelastic shape memory alloys by digital image correlation. In: Kohl M, Chernenko V (eds) 3rd International symposium on shape memory materials for smart systems/E-MRS spring meeting. Vol. 10. Physics procedia. Elsevier, Amsterdam, pp 4–10

186.

Lackmann J, Regenspurger R, Maxisch M, Grundmeier G, Maier HJ (2010) Defect formation in thin polyelectrolyte films on polycrystalline NiTi substrates. J Mech Behav Biomed Mater 3:436–445

187.

Dadda J, Maier H, Karaman I, Chumlyakov Y (2010) High-temperature in-situ microscopy during stress-induced phase transformations in Co₄₉Ni₂₁Ga₃₀ shape memory alloy single crystals. Int J Mater Res 101:1503–1513

188.

Merzouki T, Collard C, Bourgeois N, Zineb TB, Meraghni F (2010) Coupling between measured kinematic fields and multicrystal SMA finite element calculations. Mech Mater 42:72–95

189.

Dilibal S, Sehitoglu H, Hamilton RF, Maier HJ, Chumlyakov Y (2010) On the volume change in Co–Ni–Al during pseudoelasticity. Mater Sci Eng A 528:2875–2881

190.

Murasawa G, Yoneyama S, Miyata K, Nishioka A, Koda T (2011) Finite element analysis and experimental measurement of deformation behavior for NiTi plate with stress concentration part under uniaxial tensile loading. Strain 47:389–397

191.

Hamilton RF, Dilibal S, Sehitoglu H, Maier HJ (2011) Underlying mechanism of dual hysteresis in NiMnGa single crystals. Mater Sci Eng A 528:1877–1881

192.

Lackmann J, Niendorf T, Maxisch M, Grundmeier G, Maier HJ (2011) High-resolution in-situ characterization of the surface evolution of a polycrystalline NiTi SMA-alloy under pseudoelastic deformation. Mater Charact 42:298–303

193.

Grolleau V, Louche H, Delobelle V, Penin A, Rio G, Liu Y, Favier D (2011) Assessment of tension-compression asymmetry of NiTi using circular bulge testing of thin plates. Scr Mater 65:347–350

194.

Reedlunn B, Churchill C, Nelson E, Daly S, Shaw J (2012) Bending of superelastic shape memory alloy tubes. Proceedings of the ASME conference on smart materials adaptive structures and intelligent systems (SMASIS 2011), vol 1. ASME, New York, pp 249–258

195.

Reedlunn B, Daly S, Shaw J (2012) Tension-torsion experiments on superelastic shape memory alloy tubes. Proceedings of the ASME conference on smart materials adaptive structures and intelligent systems, vol 2. ASME, New York, pp 213–222

196.

Taillebot V, Lexcellent C, Vacher P (2012) About the transformation phases zones of shape memory alloys’ fracture tests on single-edge-craked specimen. Funct Mater Lett 05:1250007

197.

Zeng P, Du H, Zhao J, Lei L, Sun GFC, Gao Y (2013) Advances on experiment, measure and numerical simulation for behaviors of material processes. In: Zhang S, Liu X, Cheng M (eds) 11th international conference on numerical methods in industrial forming processes (NUMIFORM 2013. Vol. 1532. AIP conference proceedings. American Institute of Physics, Melville, pp 38–44

198.

Chemisky Y, Echchorfi R, Meraghni F, Bourgeois N, Piotrowski B (2013) Determination of the characteristic parameters of tension-compression asymmetry of shape memory alloys using full-field measurements. In: Prokoshkin S, Resnina N (eds) European symposium on martensitic transformations. Vol. 738–739. Materials science forum. Trans Tech Publications Ltd, Zurich

199.

Bewerse C, Gall KR, Mcfarland GJ, Zhu P, Brinson LC (2013) Local and global strains and strain ratios in shape memory alloys using digital image correlation. Mater Sci Eng A 568:134–142

200.

Bubulinca C, Balandraud X, Delpueyo D, Grédiac M, Stanciu S, Abrudeanu M, Plaiasu AG, Dicu MM, Nitu EL (2013) Study of a monocrystalline Cu–Al–Ni shape memory alloy by infrared thermography. J Optoelectron Adv Mater 15:544–549

201.

He H, Saletti D, Pattofatto S, Shi F, Zhao H (2013) Experimental observation of phase transformation front of SMA under impact loading. In: Prokoshkin S, Resnina N (eds) 13th international conference on fracture 2013 (ICF-13), vol 4. International Congress on Fracture (ICF), Atlanta, pp 2658–2666

202.

Chen X, He Y, Moumni Z (2013) Twin boundary motion in NiMnGa single crystals under biaxial compression. Mater Lett 90:72–75

203.

Kim K, Daly S (2013) The effect of texture on stress-induced martensite formation in nickel–titanium. Smart Mater Struct 22:075012

204.

Watkins R, Reedlunn B, Shaw J (2014) Uniaxial, pure bending and buckling characterization of superelastic NiTi rods and tubes: an experimental study. Proceedings of the ASME conference on smart materials adaptive structures and intelligent systems, vol 2. ASME, New York

205.

Cornell S, Leser W, Hochhalter J, Newman J, Hartl J (2014) Development and characterization of embedded sensory particles using multi-scale 3D digital image correlation. Proceedings of the ASME conference on smart materials adaptive structures and intelligent systems, vol 2. ASME, New York

206.

Pinneker V, Gueltig M, Sozinov A, Kohl M (2014) Single phase boundary actuation of a ferromagnetic shape memory foil. Acta Mater 64:179–187

207.

Bechle N, Kyriakides S (2014) Localization in NiTi tubes under bending. Int J Solids Struct 51:967–980

208.

Shafaghi N, Haghgouyan B, Aydiner CC, Anlas G (2015) Experimental and computational evaluation of crack-tip displacement field and transformation zone in NiTi. Mater Today Proc 2:S763–S766

209.

Sgambitterra E, Lesci S, Maletta C (2015) Effects of higher order terms in fracture mechanics of shape memory alloys by digital image correlation. In: Iacoviello F, Ferro G, Susmel L (eds) XXIII Italian group of fracture meeting, IGFXXIII. Vol. 109. Procedia Engineering. Elsevier, Amsterdam, pp 457–464

210.

Chemisky Y, Meraghni F, Bourgeois N, Cornell S, Echchorfi R, Patoor E (2015) Identification of model parameter for the simulation of SMA structures using full field measurements. In: Karaman I, Arroyave R, Masad E (eds) Proceedings of the TMS middle east—Mediterranean materials congress on energy and infrastructure systems (MEMA 2015). Wiley, Malden, pp 191–200

211.

Chemisky Y, Meraghni F, Bourgeois N, Cornell S, Echchorfi R, Patoor E (2015) Analysis of the deformation paths and thermomechanical parameter identification of a shape memory alloy using digital image correlation over heterogeneous tests. Int J Mech Sci 96–97:13–24

212.

Elibol C, Wagner MFX (2015) Investigation of the stress-induced martensitic transformation in pseudoelastic NiTi under uniaxial tension, compression and compression-shear. Mater Sci Eng A 621:76–81

213.

Patriarca L, Sehitoglu H (2015) High-temperature superelasticity of Ni_50.6Ti_24.4Hf_25.0 shape memory alloy. Scr Mater 101:12–15

214.

El-Tahan M, Dawood M, Song G (2015) Development of a self-stressing NiTiNb shape memory alloy (SMA)/fiber reinforced polymer (FRP) patch. Smart Mater Struct 24:065035

215.

Lanba A, Hamilton RF (2015) The impact of martensite deformation on shape memory effect recovery strain evolution. Metall Mater Trans A 46:3481–3489

216.

Kimiecik M, Jones JW, Daly S (2015) Grain orientation dependence of phase transformation in the shape memory alloy Nickel–Titanium. Acta Mater 94:214–223

217.

Laydi M, Lexcellent C (2015) Phase transformation surfaces analysis for SMA around a crack tip with curvature. Shap Mem Superelasticity 1:339–346

218.

Ojha A, Alkan S, Patriarca L, Sehitoglu H, Chumlyakov Y (2015) Shape memory behavior in Fe₃Al-modeling and experiments. Philos Mag 95:2553–2570CrossRef

219.

Ojha A, Patriarca L, Sehitoglu H (2015) Pseudoelasticity in Fe₃Ga with boron—combined atomistic-micromechanical treatment. Int J Plasticity 72:185–199

220.

Elibol C, Wagner X (2015) Strain rate effects on the localization of the stress-induced martensitic transformation in pseudoelastic NiTi under uniaxial tension, compression and compression-shear. Mater Sci Eng A 643:194–202

221.

Wu Y, Patriarca L, Li G, Sehitoglu H, Soejima Y, Ito T, Nishida M (2015) Shape memory response of polycrystalline NiTi_12.5Hf alloy: transformation at small scales. Shap Mem Superelasticity 1:387–397

222.

Sgambitterra E, Maletta C, Furgiuele F (2015) Investigation on crack tip transformation in NiTi alloys: effect of the temperature. Shap Mem Superelasticity 1:275–283

223.

Xiao Y, Zeng P, Lei L (2016) Experimental investigation on the mechanical instability of superelastic NiTi shape memory alloy. J Mater Eng Perform 25:3551–3557

224.

Ossmer H, Chluba C, Quandt E, Kohl M (2016) TiNi-based films for elastocaloric microcooling—fatigue life and device performance. APL Mater 4:064102

225.

Xiao Y, Zeng P, Lei L (2016) Experimental investigation on local mechanical response of superelastic NiTi shape memory alloy. Smart Mater Struct 25:105701

226.

Patriarca L, Sehitoglu H, Panchenko E, Chumlyakov Y (2016) High-temperature functional behavior of single crystal Ni_51.2Ti_23.4Hf_25.4 shape memory alloy. Acta Mater 106:333–343

227.

Kimiecik M, Jones JW, Daly S (2016) The effect of microstructure on stress-induced martensitic transformation under cyclic loading in the SMA Nickel–Titanium. J Mech Phys Solids 89:16–30

228.

Patriarca L, Wu Y, Sehitoglu H, Chumlyakov Y (2016) High temperature shape memory behavior of Ni_50.3Ti₂₅Hf_24.7 single crystals. Scr Mater 115:133–136

229.

Wu Y, Patriarca L, Sehitoglu H, Chumlyakov Y (2016) Ultrahigh tensile transformation strains in new Ni_50.5Ti_36.2Hf_13.3 shape memory alloy. Scr Mater 118:51–54

230.

Haghgouyan B, Shafaghi N, Aydıner C, Anlas G (2016) Experimental and computational investigation of the effect of phase transformation on fracture parameters of an SMA. Smart Mater Struct 25:075010

231.

LePage WS, Daly SH, Shaw JA (2016) Cross polarization for improved digital image correlation. Exp Mech 56:969–985

232.

Bimber BA, Hamilton RF, Keist J, Palmer TA (2016) Anisotropic microstructure and superelasticity of additive manufactured NiTi alloy bulk builds using laser directed energy deposition. Mater Sci Eng A 674:125–134

233.

Xiao Y, Zeng P, Lei L (2016) Experimental observations on mechanical response of three-phase NiTi shape memory alloy under uniaxial tension. Mater Res Express 3:105701

234.

Xiao Y, Zeng P, Lei L (2016) Effect of double-edge semi-circular notches on the mechanical response of superelastic NiTi shape memory alloy: experimental observations. J Strain Anal Eng Des 51:555–562

235.

Murasawa G, Yeduru SR, Kohl M (2016) Macroscopic inhomogeneous deformation behavior arising in single crystal Ni–Mn–Ga foils under tensile loading. Opt Lasers Eng 87:139–145

236.

Gong J, Daly S (2016) Microscale repeatability of the shape-memory effect in fine NiTi wires. Shap Mem Superelasticity 2:298–309

237.

Maletta C, Sgambitterra E, Niccoli F (2016) Temperature dependent fracture properties of shape memory alloys: novel findings and a comprehensive model. Sci Rep 6:17

238.

Wheeler R, Ottmers C, Hewling B, Lagoudas D (2016) Actuator lifetime predictions for Ni₆₀Ti₄₀ shape memory alloy plate actuators. In: Goulbourne N (ed) Behavior and mechanics of multifunctional materials and composites 2016. International Society for Optics and Photonics, Bellingham

239.

Xie X, Kan Q, Kang G, Lu F, Chen K (2016) Observation on rate-dependent cyclic transformation domain of super-elastic NiTi shape memory alloy. Mater Sci Eng A 671:32–47

240.

Sehitoglu H, Wu Y, Alkan S, Ertekin E (2017) Plastic deformation of B2-NiTi—is it slip or twinning? Philos Mag Lett 97:217–228

241.

Niccoli F, Garion C, Maletta C, Sgambitterra E, Furgiuele F, Chiggiato P (2017) Beam-pipe coupling in particle accelerators by shape memory alloy rings. Mater Des 114:603–611

242.

Xiao Y, Zeng P, Lei L (2017) Grain size effect on mechanical performance of nanostructured superelastic NiTi alloy. Mater Res Express 4:035702

243.

Sehitoglu H, Wu Y, Patriarca L (2017) Shape memory functionality under multi-cycles in NiTiHf. Scr Mater 129:11–15

244.

Laplanche G, Birk T, Schneider S, Frenzel J, Eggeler G (2017) Effect of temperature and texture on the reorientation of martensite variants in NiTi shape memory alloys. Acta Mater 127:143–152

245.

Abuzaid W, Sehitoglu H (2017) Functional fatigue of Ni_50.3Ti₂₅Hf_24.7. Heterogeneities and evolution of local transformation strains. Mater Sci Eng A 696:482–492

246.

Jiang D, Kyriakides S, Bechle NJ, Landis CM (2017) Bending of pseudoelastic NiTi tubes. Int J Solids Struct 124:192–214

247.

Zheng B, Dawood M (2017) Fatigue strengthening of metallic structures with a thermally activated shape memory alloy fiber-reinforced polymer patch. J Compos Constr 21:04016113

248.

Paul PP, Paranjape HM, Amin-Ahmadi B, Stebner AP, Dunand DC, Brinson LC (2017) Effect of machined feature size relative to the microstructural size on the superelastic performance in polycrystalline NiTi shape memory alloys. Mater Sci Eng A 706:227–235

249.

Xiao Y, Zeng P, Lei L, Zhang Y (2017) In situ observation on temperature dependence of martensitic transformation and plastic deformation in superelastic NiTi shape memory alloy. Mater Des 134:111–120

250.

Zheng L, He Y, Moumni Z (2017) Investigation on fatigue behaviors of NiTi polycrystalline strips under stress-controlled tension via in-situ macro-band observation. Int J Plast 90:116–145

251.

Shayanfard P, Heller L, Dostalova D, Alarcon E, Frost M, Sedlak P, Sandera P, Sittner P, Pokluda J, Hornikova J (2017) Effect of martensitic transformation on local stresses and strains at a notch of cyclically loaded superelastic NiTi ribbon. In: Gdoutos E (ed) 14th International Conference on Fracture 2017 (ICF-14), June 18–23, 2017. ICF, Rhodes

252.

Zotov N, Pfund M, Polatidis E, Mark A, Mittemeijer E (2017) Change of transformation mechanism during pseudoelastic cycling of NiTi shape memory alloys. Mater Sci Eng A 682:178–191

253.

Paranjape H, Paul P, Amin-Ahmadi B, Sharma H, Dale D, Ko J, Chumlyakov Y, Brinson L, Stebner A (2018) In situ, 3D characterization of the deformation mechanics of a superelastic NiTi shape memory alloy single crystal under multiscale constraint. Acta Mater 144:748–757

254.

Alkan S, Wu Y, Sehitoglu H (2017) Giant non-Schmid effect in NiTi. Extreme Mech Lett 15:38–43

255.

Dilibal S, Hamilton R, Lanba A (2017) The effect of employed loading mode on the mechanical cyclic stabilization of NiTi shape memory alloys. Intermetallics 89:1–9

256.

Bielefeldt B, Hochhalter J, Hartl D (2018) Shape memory alloy sensory particles for damage detection: experiments, analysis, and design studies. Struct Health Monit 17:777–814

257.

Bian X, Saleh A, Pereloma E, Davies C, Gazder A (2018) A digital image correlation study of a NiTi alloy subjected to monotonic uniaxial and cyclic loading-unloading in tension. Mater Sci Eng A 726:102–112

258.

Sittner P, Sedlak P, Seiner H, Sedmak P, Pilch J, Delville R, Heller L, Kaderavek L (2018) On the coupling between martensitic transformation and plasticity in NiTi: experiments and continuum based modelling. Prog Mater Sci 98:249–298

259.

Zhang S, He Y (2018) Fatigue resistance of branching phase-transformation fronts in pseudoelastic NiTi polycrystalline strips. Int J Solids Struct 135:233–244

260.

Chen D, Sun S, Dulieu-Barton J, Li Q, Wang W (2018) Crack growth analysis in welded and non-welded T-joints based on lock-in digital image correlation and thermoelastic stress analysis. Int J Fatigue 110:172–185

261.

Hsu W, Polatidis E, Smid M, Casati N, Van Petegem S, Van Swygenhoven H (2018) Load path change on superelastic NiTi alloys: In situ synchrotron XRD and SEM DIC. Acta Mater 144:874–883

262.

LePage W, Ahadi A, Lenthe W, Sun Q, Pollock T, Shaw J, Daly S (2018) Grain size effects on NiTi shape memory alloy fatigue crack growth. J Mater Res 33:91–107

263.

Zhang S, Chen X, Moumni Z, He Y (2018) Thermal effects on high-frequency magnetic-field-induced martensite reorientation in ferromagnetic shape memory alloys: an experimental and theoretical investigation. Int J Plasticity 108:1–20

264.

Zhang S, Chen X, Moumni Z, He Y (2018) Coexistence and compatibility of martensite reorientation and phase transformation in high-frequency magnetic-field-induced deformation of Ni–Mn–Ga single crystal. Int J Plasticity 110:110–122

265.

Bian X, Gazder A, Saleh A, Pereloma E (2018) A comparative study of a NiTi alloy subjected to uniaxial monotonic and cyclic loading-unloading in tension using digital image correlation: the grain size effect. J Alloys Compd 777:723–735

266.

Elibol C, Wagner M (2018) Virtual extensometer analysis of martensite band nucleation, growth, and strain softening in pseudoelastic NiTi subjected to different load cases. Materials 11:1458

267.

Sgambitterra E, Maletta C, Furgiuele F, Sehitoglu H (2018) Fatigue crack propagation in [012] NiTi single crystal alloy. Int J Fatigue 112:9–20

268.

Bucsek A, Dale D, Ko J, Chumlyakov Y, Stebner A (2018) Measuring stress-induced martensite microstructures using far-field high-energy diffraction microscopy. Acta Crystallogr A 74:425–446

269.

Bucsek A, Pagan D, Casalena L, Chumlyakov Y, Mills M, Stebner A (2019) Ferroelastic twin reorientation mechanisms in shape memory alloys elucidated with 3D X-ray microscopy. J Mech Phys Solids 124:897–928

270.

Chen Y, Tyc O, Kaderavek L, Molnarova O, Heller L, Sittner P (2019) Temperature and microstructure dependence of localized tensile deformation of superelastic NiTi wires. Mater Des 174:107797

271.

Kazinakis K, Kyriakides S, Jiang D, Bechle N, Landis C (2021) Buckling and collapse of pseudoelastic NiTi tubes under bending. Int J Solids Struct 221:2–17

272.

Heller L, Šittner P, Sedlák P, Seiner H, Tyc O, Kadeřávek L, Sedmák P, Vronka M (2019) Beyond the strain recoverability of martensitic transformation in NiTi. Int J Plast 116:232–264

273.

Shuai J, Xiao Y (2019) In-situ study on texture-dependent martensitic transformation and cyclic irreversibility of superelastic NiTi shape memory alloy. Metall Mater Trans A 51:562–567

274.

Wu Y, Yaacoub J, Brenne F, Abuzaid W, Canadinc D, Sehitoglu H (2019) Deshielding effects on fatigue crack growth in shape memory alloys—a study on CuZnAl single-crystalline materials. Acta Mater 176:155–166

275.

Catoor D, Ma Z, Kumar S (2019) Cyclic response and fatigue failure of Nitinol under tension tension loading. J Mater Res 34:3504–3522

276.

Bahador A, Umeda J, Tsutsumi S, Hamzah E, Yusof F, Fujii H, Kondoh K (2019) Asymmetric local strain, microstructure and superelasticity of friction stir welded Nitinol alloy. Mater Sci Eng A 767:138344

277.

Kumar S, Marandi L, Balla V, Bysakh S, Piorunek D, Eggeler G, Das M, Sen I (2019) Microstructure—property correlations for additively manufactured NiTi based shape memory alloys. Materialia 8:100456

278.

Kyianytsia A, Ponçot M, Letoffe A, Boulet P, Migot S, Ghanbaja J, Cinar I, de Miranda R, Bechtold C, Kierren B, Ozatay O, Hauet T (2019) Magnetic anisotropy switching induced by shape memory effect in NiTi/Ni bilayer. Appl Phys Lett 115:222402

279.

Ma L, Li Y, Han G (2019) Study on fracture behavior of NiTi alloy by the digital image correlation method. In: Khotsianovsky A (ed) 7th global conference on materials science and engineering (CMSE2018). Vol. 474. IOP conference series—materials science and engineering. IOP Publishing Ltd, Bristol

280.

Sgambitterra E, Magaro P, Niccoli F, Renzo D, Maletta C (2019) Novel insight into the strain-life fatigue properties of pseudoelastic NiTi shape memory alloys. Smart Mater Struct 28:10LT03

281.

Wheeler R, Smith J, Ley N, Giri A, Young M (2019) Shape memory behavior of Ni_49.5Ti_50.5 processing-induced strain glass alloys. TMS 2019 148th annual meeting & exhibition supplemental proceedings. Minerals metals & materials series. Springer, Cham, pp 1411–1420

282.

Young B, Haghgouyan B, Lagoudas D, Karaman I (2019) Effect of temperature on the fracture toughness of a NiTiHf high temperature shape memory alloy. Shap Mem Superelasticity 5:362–373

283.

Bian X, Saleh A, Lynch P, Davies C, Pereloma E, Gazder A (2019) An in-situ synchrotron study of the B2 -> B19’ phase transformation in a Ni–Ti alloy subjected to uniaxial monotonic tension. Mater Sci Eng A 743:327–338

284.

Sgambitterra E, Maletta C, Magaro P, Renzo D, Furgiuele F, Sehitoglu H (2019) Effects of temperature on fatigue crack propagation in pseudoelastic NiTi shape memory alloys. Shap Mem Superelasticity 5:278–291

285.

Sgambitterra E, Magaro P, Niccoli F, Renzo D, Maletta C (2019) Low-to-high cycle fatigue properties of a NiTi shape memory alloy. In: Iacoviello F, Susmel L, Firrao D, Ferro G (eds) 25th international conference on fracture and structural integrity. Vol. 18. Procedia structural integrity. Elsevier, Amsterdam, pp 908–913

286.

Zeng Z, Cong B, Oliveira J, Ke W, Schell N, Peng B, Qi Z, Ge F, Zhang W, Ao S (2020) Wire and arc additive manufacturing of a Ni-rich NiTi shape memory alloy: microstructure and mechanical properties. Addit Manuf 32:101051

287.

Paranjape H, Ng B, Ong I, Vien L, Huntley C (2020) Phase transformation volume amplitude as a low-cycle fatigue indicator in nickel-titanium shape memory alloys. Scr Mater 178:442–446

288.

Suhail R, Chen J, Amato G, McCrum D (2020) Mechanical behaviour of NiTiNb shape memory alloy wires—strain localization and effect of strain rate. Mech Mater 144:103346

289.

Mohajeri M, Case R, Haghgouyan B, Lagoudas D, Castaneda H (2020) Loading influence on the corrosion assessment during stress-induced martensite reorientation in nickel-titanium SMA. Smart Mater Struct 29:035013

290.

Zhao H, Andrawes B (2020) Innovative prestressing technique using curved shape memory alloy reinforcement. Constr Build Mater 238:117687

291.

Suhail R, Amato G, McCrum D (2020) Heat-activated prestressing of NiTib shape memory alloy wires. Eng Struct 206:110128

292.

Sidharth R, Wu Y, Brenne F, Abuzaid W, Sehitoglu H (2020) Relationship between functional fatigue and structural fatigue of iron-based shape memory alloy FeMnNiAl. Shape Mem Superelasticity 6:256–272

293.

Li C, Ao S, Oliveira J, Cheng M, Zeng Z, Cui H, Luo Z (2020) Ultrasonic spot welded NiTi joints using an aluminum interlayer: Microstructure and mechanical behavior. J Manuf Process 56:1201–1210

294.

Reedlunn B, LePage W, Daly S, Shaw J (2020) Axial-torsion behavior of superelastic tubes: part I, proportional isothermal experiments. Int J Solids Struct 199:1–35

295.

Su T, Lu N, Chen C, Chen C (2020) Full-field stress and strain measurements revealing energy dissipation characteristics in martensitic band of Cu–Al–Mn shape memory alloy. Mater Today Commun 24:101321

296.

Samothrakitis S, Larsen CB, Woracek R, Heller L, Kopeček J, Gerstein G, Maier HJ, Rameš M, Tovar M, Šittner P, Schmidt S, Strobl M (2020) A multiscale study of hot-extruded CoNiGa ferromagnetic shape-memory alloys. Mater Des 196:109118

297.

Aycock K, Weaver J, Paranjape HM, Senthilnathan K, Bonsignore C, Craven B (2021) Full-field microscale strain measurements of a nitinol medical device using digital image correlation. J Mech Behav Biomed Mater 114:104221

298.

Shen V, Bumgardner C, Actis L, Ritz J, Park J, Li X (2020) 3D digital image correlation evaluation of arthrodesis implants. Clin Biomech 71:29–36

299.

Suhail R, Amato G, McCrum D (2020) Heat-activated prestressing of NiTiNb shape memory alloy wires. Eng Struct 206:110128

300.

Xiao R, Hou B, Sun Q, Zhao H, Li Y (2020) An experimental investigation of the nucleation and the propagation of NiTi martensitic transformation front under impact loading. Int J Impact Eng 140:103559

301.

Shariat BS (2020) Experimental investigation of heterogeneous strain fields created in metallic materials. In: IOP Publishing (ed) 2019 7th International Conference on Mechanical, Automative and Materials Engineering (CMAME), vol 831. IOP Conference Series-Materials Science and Engineering, IOP Publishing Ltd, Bristol, England, p 012006

302.

Safaei K, Nematollahi M, Bayati P, Dabbaghi H, Benafan O, Elahinia M (2021) Torsional behavior and microstructure characterization of additively manufactured NiTi shape memory alloy tubes. Eng Struct 226:111383

303.

Paranjape H, Aycock K, Bonsignore C, Weaver J, Craven B, Duerig T (2021) A probabilistic approach with built-in uncertainty quantification for the calibration of a superelastic constitutive model from full-field strain data. Comput Mater Sci 192:110357

304.

Abut B, Haghgouyan B, Karaman I, Lagoudas D (2021) Effect of specimen thickness on the fracture toughness of a NiTi shape memory alloy. Shap Mem Superelasticity 7:90–100

305.

Sgambitterra E, Magaro P, Niccoli F, Furgiuele F, Maletta C (2021) Fatigue crack growth in austenitic and martensitic NiTi: modeling and experiments. Shap Mem Superelasticity 7:250–261

306.

Bauer A, Vollmer M, Niendorf T (2021) Effect of crystallographic orientation and grain boundaries on martensitic transformation and superelastic response of oligocrystalline Fe–Mn–Al–Ni shape memory alloys. Shap Mem Superelasticity 7:373–382

307.

Elibol C (2021) Superelastic anisotropy and meso-scale interface regions in textured NiTi sheets. J Fac Eng Archit Gazi Univ 36:2121–2133

308.

Patriarca L, Abuzaid W, Carlucci G, Belelli F, Casati R (2021) Pseudoelasticity in FeMn–NiAl shape memory alloy lattice structures produced by laser powder bed fusion. Mater Lett 302:130349

309.

Su T, Lu N, Chen C, Chen C (2021) On the decrease in transformation stress in a bicrystal Cu–Al–Mn shape-memory alloy during cyclic compressive deformation. Materials 14:4439

310.

Xiao R, Hou B, Sun Q, Zhao H, Li Y (2021) Mechanical behaviors of polycrystalline NiTi SMAs of various grain sizes under impact loading. Sci China Ser E Technol Sci 64:1401–1411

311.

Qing X, Qin Y, Dai F (1996) Experimental investigation of micromechanical behavior of advanced materials by moiré interferometry. Opt Lasers Eng 25:179–189

312.

Zhang X, Sun Q, Yu S (1999) On the strain jump in shape memory alloys. A crystallographic—based mechanics analysis. Acta Mech Sin 15:134–144

313.

Sun Q, Xu T, Zhang X (1999) On deformation of A–M interface in single crystal shape memory alloys and some related issues. J Eng Mater Technol ASME 121:38–43

314.

Zhang XY, Sun QP, Yu SW (2000) A non-invariant plane model for the interface in CuAlNi single crystal shape memory alloys. J Mech Phys Solids 48:2163–2182

315.

Tse K, Sun Q (2000) Some deformation features of polycrystalline superelastic NiTi shape memory alloy thin strips and wires under tension. In: Yu T, Sun Q, Kim J (eds) Advances in engineering plasticity, PTS 1–2. Vol. 177–1. Key engineering materials. Trans Tech Publications Ltd, Zurich, pp 455–460

316.

Fang D, Liu J, Xu G, Dai F (2000) Micromechanical study of formation and evolution of martensite for Cu–Al–Ni single crystal by moiré interferometry. Theor Appl Fract Mech 33:49–55

317.

Jonnalagadda KD, Sottos NR, Qidwai MA, Lagoudas D (2000) In situ displacement measurements and numerical predictions of embedded SMA transformation. Smart Mater Struct 9:701–710

318.

Du H, Xie H, Jiang H, Rong L, Luo Q, Gu C, Zhao Y (2006) Strain analysis on porous TiNi SMA using SEM moiré method. In: Lee S, Kim Y (eds) Experimental mechanics in nano and biotechnology, Pts 1 and 2. Vol. 326–328. Key engineering materials. Trans Tech Publications Ltd, Zurich, pp 79–82

319.

Perry KE, Labossiere PE, Steffler E (2007) Measurement of deformation and strain in nitinol. Exp Mech 47:373–380

320.

Du H, Xie H, Guo Z, Pan B, Luo Q, Gu C, Jiang H, Rong L (2007) Large-deformation analysis in microscopic area using micro-moiré methods with a focused ion beam milling grating. Opt Lasers Eng 45:1157–1169

321.

Xie H, Kishimoto S, Li Y, Liu D, Zhang M, Hu Z (2008) Deformation Analysis of Shape Memory Alloy Using SEM Scanning Moiré Method. In: Yang W, Geni M, Wang T, Zhuang Z (eds) Advances in fracture and materials behavior, PTS 1-2. Vol. 33–37. Advanced materials research. Trans Tech Publications Ltd, Zurich

322.

Wang Q, Xie H, Jiang H, Li Y, Dai F, Chen P, Zhang Q, Huang F (2008) Investigation on the deformation of TiNi shape memory alloy with a crack using moiré interferometry. Adv Mater Res 33–37:1–6

323.

Guo Z, Xie H, Dai F, Qiang H, Rong L, Chen P, Huang F (2009) Compressive behavior of 64% porosity NiTi alloy: an experimental study. Mater Sci Eng A 515:117–130

324.

Balandraud X, Barrera N, Biscari P, Grédiac M, Zanzotto G (2015) Strain intermittency in shape-memory alloys. Phys Rev B 91:174111

325.

Blaysat B, Balandraud X, Grédiac M, Vives E, Barrera N, Zanzotto G (2020) Concurrent tracking of strain and noise bursts at ferroelastic phase fronts. Commun Mater 1:3

326.

Lanba A, Hamilton R (2013) NiTi-based SMAs for self-post-tensioned bridge girders. In: Bakis C (ed) Proceedings of the American Society for Composites, vol 2. Destech Publications, Lancaster, pp 1640–1649

Springer Professional

Applying Full-Field Measurement Techniques for the Thermomechanical Characterization of Shape Memory Alloys: A Review and Classification

Abstract

Graphical Abstract

Premium Partner

Marktübersichten

Springer Professional

Abstract

Graphical Abstract

Bitte loggen Sie sich ein, um Zugang zu Ihrer Lizenz zu erhalten.

Weitere Artikel der Ausgabe 4/2021

Cardiovascular Implant Durability Conference (CVID) Rescheduled to April

Effect of Ni/Ti Ratio and Ta Content on NiTiTa Alloys

SMST 2022 Conference to be Held in San Diego, California

Microstructural, Mechanical, and Superelastic Behavior of Thermo-Mechanically Processed Nitinol Alloy

Continuous Heating Dissolution and Continuous Cooling Precipitation Diagrams of a Nickel-Titanium Shape Memory Alloy

Effect of Ce and Sb Elements Addition on Porous Ti–23 wt%Nb–Sn for Biomedical Applications

Premium Partner

Marktübersichten