Skip to main content
Fachgebiete
Automobil + Motoren Bauwesen + Immobilien Business IT + Informatik Elektrotechnik + Elektronik Energie + Nachhaltigkeit Finance + Banking Management + Führung Marketing + Vertrieb Maschinenbau + Werkstoffe Versicherung + Risiko
DE
EN
Bücher
Zeitschriften
Themenseiten
Organisationspsychologie Projektmanagement Marketing Smart Manufacturing
Weitere Formate
Podcasts Webinare Technik Webinare Wirtschaft Kongresse Veranstaltungskalender Awards
Jetzt Einzelzugang starten
Zugang für Unternehmen
Referenzkunden
SLX-Digitalkonferenz: Zukunftswerkstatt 2024

Mehr Umsatz mit Top-Kontakten

Am 7. Mai erfahren Sie, wie Vertriebsteams Leadgenerierung, Leadnurturing und Leadstrategien effizient steuern können.
Erweiterte Suche
Anmelden
nach oben
Shape Memory and Superelasticity
Erschienen in: Shape Memory and Superelasticity 4/2015

01.12.2015

Recent Developments in High-Temperature Shape Memory Thin Films

verfasst von: Y. Motemani, P. J. S. Buenconsejo, A. Ludwig

Erschienen in: Shape Memory and Superelasticity | Ausgabe 4/2015

Einloggen

Aktivieren Sie unsere intelligente Suche, um passende Fachinhalte oder Patente zu finden.

search-config
loading …

Abstract

High-temperature shape memory alloy (HTSMA) thin films are candidates for development of microactuators with operating temperatures exceeding 100 °C. This article reviews recent advances and developments in the field of HTSMA thin films during the past decade, with focus on the systems Ti–Ni–X (X = Hf, Zr, Pd, Pt and Au), Ti–Ta, and Au–Cu–Al. These actuator films offer a wide range of transformation temperatures, thermal hysteresis, and recoverable strains suitable for high-temperature applications. Promising alloy compositions in the systems Ti–Ni–Hf, Ti–Ni–Pd, Ti–Ni–Au, and Au–Cu–Al are highlighted for further upscaling and development. The remaining challenges as well as prospects for development of HTSMA thin films are also discussed.
Vorheriger Artikel Computational Thermodynamics and Kinetics-Based ICME Framework for High-Temperature Shape Memory Alloys
Nächster Artikel Active Cooling and Strain-Ratios to Increase the Actuation Frequency of SMA Wires

Sie haben noch keine Lizenz? Dann Informieren Sie sich jetzt über unsere Produkte:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

  • über 102.000 Bücher
  • über 537 Zeitschriften

aus folgenden Fachgebieten:

  • Automobil + Motoren
  • Bauwesen + Immobilien
  • Business IT + Informatik
  • Elektrotechnik + Elektronik
  • Energie + Nachhaltigkeit
  • Finance + Banking
  • Management + Führung
  • Marketing + Vertrieb
  • Maschinenbau + Werkstoffe
  • Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

  • über 67.000 Bücher
  • über 390 Zeitschriften

aus folgenden Fachgebieten:

  • Automobil + Motoren
  • Bauwesen + Immobilien
  • Business IT + Informatik
  • Elektrotechnik + Elektronik
  • Energie + Nachhaltigkeit
  • Maschinenbau + Werkstoffe




 

Jetzt Wissensvorsprung sichern!

Jetzt informieren
Literatur
1.
Ma J, Karaman I, Noebe RD (2010) High temperature shape memory alloys. Int Mater Rev 55(5):257–315CrossRef
2.
Van Humbeeck J (2012) Shape memory alloys with high transformation temperatures. Mater Res Bull 47(10):2966–2968CrossRef
3.
Bellouard Y (2008) Shape memory alloys for microsystems: a review from a material research perspective. Mater Sci Eng A 481–482:582–589CrossRef
4.
Wei ZG, Sandstroröm R, Miyazaki S (1998) Shape-memory materials and hybrid composites for smart systems: part I Shape-memory materials. J Mater Sci 33(15):3743–3762CrossRef
5.
Krulevitch P, Lee AP, Ramsey PB, Trevino JC, Hamilton J, Northrup MA (1996) Thin film shape memory alloy microactuators. J Microelectromech Syst 5(4):270–282CrossRef
6.
Miyazaki S, Fu Y, Huang W (2009) Thin film shape memory alloys: fundamentals and device applications. Cambridge University Press, New YorkCrossRef
7.
Fu Y, Du H, Huang W, Zhang S, Hu M (2004) TiNi-based thin films in MEMS applications: a review. Sens Actuators A 112(2–3):395–408CrossRef
8.
Tomozawa M, Okutsu K, Kim HK, Miyazaki S (2005) Characterization of high-speed microactuator utilizing shape memory alloy thin films. Mater Sci Forum 475–479:2037–2042CrossRef
9.
Buenconsejo PJS, Ludwig A (2014) Composition–structure–function diagrams of Ti–Ni–Au thin film shape memory alloys. ACS Comb Sci 16(12):678–685CrossRef
10.
Buenconsejo PJS, Ludwig A (2015) New Au–Cu–Al thin film shape memory alloys with tunable functional properties and high thermal stability. Acta Mater 85:378–386CrossRef
11.
Motemani Y, McCluskey PJ, Zhao C, Tan MJ, Vlassak JJ (2011) Analysis of Ti–Ni–Hf shape memory alloys by combinatorial nanocalorimetry. Acta Mater 59(20):7602–7614CrossRef
12.
Zarnetta R, Zelaya E, Eggeler G, Ludwig A (2009) Influence of precipitates on the thermal hysteresis of Ti–Ni–Pd shape memory thin films. Scr Mater 60(5):352–355CrossRef
13.
König D, Zarnetta R, Savan A, Brunken H, Ludwig A (2011) Phase transformation, structural and functional fatigue properties of Ti–Ni–Hf shape memory thin films. Acta Mater 59(8):3267–3275CrossRef
14.
Ludwig A, Buenconsejo PJS, Butera F (2012) Recent developments in shape memory materials and technology: thin film and bulk, actuator 2012. In: 13th international conference on new actuators. Bremen, Germany, pp 486–491
15.
McCluskey PJ, Xiao K, Gregoire JM, Dale D, Vlassak JJ (2015) Application of in situ nano-scanning calorimetry and X-ray diffraction to characterize Ni–Ti–Hf high-temperature shape memory alloys. Thermochim Acta 603:53–62CrossRef
16.
McCluskey PJ, Zhao C, Kfir O, Vlassak JJ (2011) Precipitation and thermal fatigue in Ni–Ti–Zr shape memory alloy thin films by combinatorial nanocalorimetry. Acta Mater 59(13):5116–5124CrossRef
17.
Zarnetta R, Savan A, Thienhaus S, Ludwig A (2007) Combinatorial study of phase transformation characteristics of a Ti–Ni–Pd shape memory thin film composition spread in view of microactuator applications. Appl Surf Sci 254(3):743–748CrossRef
18.
Butera F, Coda A, Motemani Y, Ludwig A (2014) Emerging SMA applications and new material developments, actuator 2014. In: 14th international conference on new actuators, Bremen, Germany, pp 203–209
19.
McCluskey PJ, Vlassak JJ (2010) Combinatorial nanocalorimetry. J Mater Res 25(11):2086–2100CrossRef
20.
Thienhaus S, Hamann S, Ludwig A (2011) Modular high-throughput test stand for versatile screening of thin-film materials libraries. Sci Technol Adv Mater 12(5):054206CrossRef
21.
Takeuchi I, Famodu OO, Read JC, Aronova MA, Chang KS, Craciunescu C, Lofland SE, Wuttig M, Wellstood FC, Knauss L, Orozco A (2003) Identification of novel compositions of ferromagnetic shape-memory alloys using composition spreads. Nat Mater 2(3):180–184CrossRef
22.
Inoue S, Sawada N, Namazu T (2008) Effect of Zr content on mechanical properties of Ti–Ni–Zr shape memory alloy films prepared by dc magnetron sputtering. Vacuum 83(3):664–667CrossRef
23.
Kim HY, Mizutani M, Miyazaki S (2009) Crystallization process and shape memory properties of Ti–Ni–Zr thin films. Acta Mater 57(6):1920–1930CrossRef
24.
Kim HY, Yuan Y, Nam TH, Miyazaki S (2011) Effect of Pd content on crystallization and shape memory properties of Ti–Ni–Pd thin films. Int J Smart Nano Mater 2(1):9–21CrossRef
25.
Kohl M, Dittmann D, Quandt E, Winzek B, Miyazaki S, Allen DM (1999) Shape memory microvalves based on thin films or rolled sheets. Mater Sci Eng A 273–275:784–788CrossRef
26.
Lee JW, Thomas B, Rabiei A (2006) Microstructural study of titanium–palladium–nickel base thin film shape memory alloys. Thin Solid Films 500(1–2):309–315CrossRef
27.
Liu Y, Kohl M, Okutsu K, Miyazaki S (2004) A TiNiPd thin film microvalve for high temperature applications. Mater Sci Eng A 378(1–2):205–209CrossRef
28.
Panduranga MK, Shin DD, Carman GP (2006) Shape memory behavior of high temperature Ti–Ni–Pt thin films. Thin Solid Films 515(4):1938–1941CrossRef
29.
Quandt E, Halene C, Holleck H, Feit K, Kohl M, Schloßmacher P, Skokan A, Skrobanck KD (1996) Sputter deposition of TiNi, TiNiPd and TiPd films displaying the two-way shape-memory effect. Sens Actuators A 53(1–3):434–439CrossRef
30.
Rao J, Roberts T, Lawson K, Nicholls J (2010) Nickel titanium and nickel titanium hafnium shape memory alloy thin films. Surf Coat Technol 204(15):2331–2336CrossRef
31.
Sakurai J, Hata S (2012) Search for Ti–Ni–Zr thin film metallic glasses exhibiting a shape memory effect after crystallization. Mater Sci Eng A 541:8–13CrossRef
32.
Sanjabi S, Cao YZ, Barber ZH (2005) Multi-target sputter deposition of Ni50Ti50−xHfx shape memory thin films for high temperature microactuator application. Sens Actuators A 121(2):543–548CrossRef
33.
Tong Y, Liu Y, Miao J (2008) Phase transformation in NiTiHf shape memory alloy thin films. Thin Solid Films 516(16):5393–5396CrossRef
34.
Tong Y, Liu Y, Miao J, Zhao L (2005) Characterization of a nanocrystalline NiTiHf high temperature shape memory alloy thin film. Scr Mater 52(10):983–987CrossRef
35.
Vitushinsky R, Schmitz S, Ludwig A (2009) Bistable thin-film shape memory actuators for applications in tactile displays. J Microelectromech Syst 18(1):186–194CrossRef
36.
Liu C, Mu HW, Gao LX, Ma WJ, An X, Gao ZY, Cai W (2010) Growth of Ni–Mn–Ga high-temperature shape memory alloy thin films by magnetron sputtering technique. Appl Surf Sci 256(22):6655–6659CrossRef
37.
Wang HB, Liu C, Lei YC, Cai W (2008) Characterization of Ni55.6Mn11.4Fe7.4Ga25.6 high temperature shape memory alloy thin film. J Alloys Compd 465(1–2):458–461CrossRef
38.
Grummon D (2003) Thin-film shape-memory materials for high-temperature applications. JOM 55(12):24–32CrossRef
39.
Zarnetta R, Ehmann M, Savan A, Ludwig A (2010) Identification of optimized Ti–Ni–Cu shape memory alloy compositions for high-frequency thin film microactuator applications. Smart Mater Struct 19(6):065032CrossRef
40.
Abujudom DN, Thoma PE, Kao MY, Angst DR (1992) High transformation temperature shape memory alloy. Patent, U. (ed.), US 07/609,377, Johnson Service Company
41.
Buenconsejo PJS, Kim HY, Hosoda H, Miyazaki S (2009) Shape memory behavior of Ti–Ta and its potential as a high-temperature shape memory alloy. Acta Mater 57(4):1068–1077CrossRef
42.
Zhang J, Rynko R, Frenzel J, Somsen C, Eggeler G (2013) Ingot metallurgy and microstructural characterization of Ti–Ta alloys. Int J Mater Res 105(2):156–167CrossRef
43.
Motemani Y, Buenconsejo PJS, Craciunescu C, Ludwig A (2014) High-Temperature shape memory effect in Ti-Ta thin films sputter deposited at room temperature. Adv Mater Interfaces 1(3):1400019CrossRef
44.
Motemani Y, Kadletz PM, Maier B, Rynko R, Somsen C, Paulsen A, Frenzel J, Schmahl WW, Eggeler G, Ludwig A (2015) Microstructure, shape Memory effect and functional stability of Ti67Ta33 thin films. Adv Eng Mater 17(10):1425–1433. doi:10.​1002/​adem.​201400576 CrossRef
45.
McCluskey PJ, Vlassak JJ (2011) Glass transition and crystallization of amorphous Ni–Ti–Zr thin films by combinatorial nano-calorimetry. Scr Mater 64(3):264–267CrossRef
46.
Niendorf T, Krooß P, Batyrsina E, Paulsen A, Frenzel J, Eggeler G, Maier HJ (2014) On the functional degradation of binary titanium–tantalum high-temperature shape memory alloys—a new concept for fatigue life extension. Funct Mater Lett 07(04):1450042CrossRef
47.
Kim HY, Fukushima T, Buenconsejo PJS, Nam T-H, Miyazaki S (2011) Martensitic transformation and shape memory properties of Ti–Ta–Sn high temperature shape memory alloys. Mater Sci Eng A 528(24):7238–7246CrossRef
48.
Buenconsejo PJS, Kim HY, Miyazaki S (2011) Novel β-TiTaAl alloys with excellent cold workability and a stable high-temperature shape memory effect. Scr Mater 64(12):1114–1117CrossRef
49.
Wolff IM, Cortie MB (1994) The development of Spangold. Gold Bull 27(2):44–54CrossRef
50.
Liu J-H, Wang A-Q, Chi Y-S, Lin H-P, Mou C-Y (2005) Synergistic effect in an Au–Ag alloy nanocatalyst: CO oxidation. J Phys Chem B 109(1):40–43CrossRef
51.
Lang XY, Guo H, Chen LY, Kudo A, Yu JS, Zhang W, Inoue A, Chen MW (2010) Novel nanoporous Au–Pd alloy with high catalytic activity and excellent electrochemical stability. J Phys Chem C 114(6):2600–2603CrossRef
52.
Chen X, Srivastava V, Dabade V, James RD (2013) Study of the cofactor conditions: conditions of supercompatibility between phases. J Mech Phys Solids 61(12):2566–2587CrossRef
53.
James RD, Zhang Z (2005) A way to search for multiferroic materials with “unlikely” combinations of physical properties. In: Planes A, Mañosa L, Saxena A (eds) Magnetism and structure in functional materials. Springer, Heidelberg, pp 159–175CrossRef
54.
Song Y, Chen X, Dabade V, Shield TW, James RD (2013) Enhanced reversibility and unusual microstructure of a phase-transforming material. Nature 502:85–88CrossRef
55.
Zarnetta R, Takahashi R, Young ML, Savan A, Furuya Y, Thienhaus S, Maaß B, Rahim M, Frenzel J, Brunken H, Chu YS, Srivastava V, James RD, Takeuchi I, Eggeler G, Ludwig A (2010) Identification of quaternary shape memory alloys with near-zero thermal hysteresis and unprecedented functional stability. Adv Funct Mater 20(12):1917–1923CrossRef
56.
König D, Naujoks D, de los Arcos T, Grosse-Kreul S, Ludwig A (2015) X-ray photoelectron spectroscopy investigations of the surface reaction layer and its effects on the transformation properties of nanoscale Ti51Ni38Cu11 shape memory thin films. Adv. Eng. Mater. 17(5):669–673CrossRef
57.
Fu YQ, Zhang S, Wu MJ, Huang WM, Du HJ, Luo JK, Flewitt AJ, Milne WI (2006) On the lower thickness boundary of sputtered TiNi films for shape memory application. Thin Solid Films 515(1):80–86CrossRef
58.
Lai A, Du Z, Gan CL, Schuh CA (2013) Shape memory and superelastic ceramics at small scales. Science 341:1505–1508CrossRef
59.
Zhang J, Ke X, Gou G, Seidel J, Xiang B, Yu P, Liang WI, Minor AM, Chu YH, Tendeloo GV, Ren X, Ramesh R (2013) A nanoscale shape memory oxide. Nat Commun. doi:10.​1038/​ncomms3768
60.
Viswanath B, Ko C, Ramanathan S (2011) Thermoelastic switching with controlled actuation in VO2 thin films. Scr Mater 64(6):490–493 CrossRef
Metadaten
Titel
Recent Developments in High-Temperature Shape Memory Thin Films
verfasst von
Y. Motemani
P. J. S. Buenconsejo
A. Ludwig
Publikationsdatum
01.12.2015
Verlag
Springer International Publishing
Erschienen in
Shape Memory and Superelasticity / Ausgabe 4/2015
Print ISSN: 2199-384X
Elektronische ISSN: 2199-3858
DOI
https://doi.org/10.1007/s40830-015-0041-0

Weitere Artikel der Ausgabe 4/2015

Shape Memory and Superelasticity 4/2015 Zur Ausgabe

OriginalPaper

Active Cooling and Strain-Ratios to Increase the Actuation Frequency of SMA Wires

OriginalPaper

Local Mechanical Response of Superelastic NiTi Shape-Memory Alloy Under Uniaxial Loading

OriginalPaper

Effect of Thermal Treatments on Ni–Mn–Ga and Ni-Rich Ni–Ti–Hf/Zr High-Temperature Shape Memory Alloys

OriginalPaper

Computational Thermodynamics and Kinetics-Based ICME Framework for High-Temperature Shape Memory Alloys

OriginalPaper

Effects of Grain Size and Co Addition on the Transformation Temperatures of Ti–Ni–Zr Thin Films

OriginalPaper

Directions for High-Temperature Shape Memory Alloys’ Improvement: Straight Way to High-Entropy Materials?

Premium Partner

    Marktübersichten

    Die im Laufe eines Jahres in der „adhäsion“ veröffentlichten Marktübersichten helfen Anwendern verschiedenster Branchen, sich einen gezielten Überblick über Lieferantenangebote zu verschaffen. 

    Zur Marktübersicht
    Bildnachweise