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Year 2017, Volume: 1 Issue: 2, 70 - 75, 15.09.2017
https://doi.org/10.31127/tuje.316254

Abstract

References

  • Canbay, C. A. (2010). The production of Cu-based shape memory alloys and investigation of microstructural, thermal and electrical properties of alloys, Ph. D Thesis, Fırat University, Institute of Science, Elazığ/Turkey (Turkish).
  • Gómez-Cortés, J., J. San Juan, G. López and M. Nó (2013). "Synthesis and characterization of Cu–Al–Ni shape memory alloy multilayer thin films." Thin Solid Films Vol. 544, No. pp. 588-592.
  • Izadinia, M. and K. Dehghani (2011). "Structure and properties of nanostructured Cu-13.2 Al-5.1 Ni shape memory alloy produced by melt spinning." Transactions of Nonferrous Metals Society of China Vol. 21, No. 9 pp. 2037-2043.
  • Karagoz, Z. and C. A. Canbay (2013). "Relationship between transformation temperatures and alloying elements in Cu–Al–Ni shape memory alloys." Journal of Thermal Analysis and Calorimetry Vol. 114, No. 3 pp. 1069-1074.
  • Kato, H., Y. Yasuda and K. Sasaki (2011). "Thermodynamic assessment of the stabilization effect in deformed shape memory alloy martensite." Acta Materialia Vol. 59, No. 10 pp. 3955-3964.
  • Kissinger, H. E. (1957). "Reaction kinetics in differential thermal analysis." Analytical chemistry Vol. 29, No. 11 pp. 1702-1706.
  • Lojen, G., I. Anžel, A. Kneissl, A. Križman, E. Unterweger, B. Kosec and M. Bizjak (2005). "Microstructure of rapidly solidified Cu–Al–Ni shape memory alloy ribbons." Journal of Materials Processing Technology Vol. 162, No. pp. 220-229.
  • Massad, J. E. and R. C. Smith (2005). "A homogenized free energy model for hysteresis in thin-film shape memory alloys." Thin Solid Films Vol. 489, No. 1 pp. 266-290.
  • Meng, Q., H. Yang, Y. Liu and T.-h. Nam (2010). "Transformation intervals and elastic strain energies of B2-B19 ′ martensitic transformation of NiTi." Intermetallics Vol. 18, No. 12 pp. 2431-2434.
  • Otsuka, K. and X. Ren (2005). "Physical metallurgy of Ti–Ni-based shape memory alloys." Progress in materials science Vol. 50, No. 5 pp. 511-678.
  • Otsuka, K. and C. Wayman (1998). "Mechanism of shape memory effect and superelasticity." Shape memory materials, No. pp. 27-48.
  • Ozawa, T. (1970). "Kinetic analysis of derivative curves in thermal analysis." Journal of Thermal Analysis and Calorimetry Vol. 2, No. 3 pp. 301-324.
  • Pérez-Landazábal, J. I., V. Recarte, V. Sánchez-Alarcos, M. L. Nó and J. S. Juan (2006). "Study of the stability and decomposition process of the β phase in Cu–Al–Ni shape memory alloys." Materials Science and Engineering: A Vol. 438–440, No. pp. 734-737.
  • Recarte, V., J. Perez-Landazabal, P. Rodrıguez, E. Bocanegra, M. No and J. San Juan (2004). "Thermodynamics of thermally induced martensitic transformations in Cu–Al–Ni shape memory alloys." Acta materialia Vol. 52, No. 13 pp. 3941-3948.
  • Sobrero, C., P. La Roca, A. Roatta, R. Bolmaro and J. Malarría (2012). "Shape memory properties of highly textured Cu–Al–Ni–(Ti) alloys." Materials Science and Engineering: A Vol. 536, No. pp. 207-215.
  • Wang, Z., X. Zu, H. Yu, X. He, C. Peng and Y. Huo (2006). "Temperature memory effect in CuAlNi single crystalline and CuZnAl polycrystalline shape memory alloys." Thermochimica acta Vol. 448, No. 1 pp. 69-72.
  • Xuan, Q., J. Bohong, T. Hsu and X. Zuyao (1987). "The effect of martensite ordering on shape memory effect in a copper-zinc-aluminium alloy." Materials Science and Engineering Vol. 93, No. pp. 205-211.

FABRICATION OF Cu-Al-Ni SHAPE MEMORY THIN FILM BY THERMAL EVAPORATION

Year 2017, Volume: 1 Issue: 2, 70 - 75, 15.09.2017
https://doi.org/10.31127/tuje.316254

Abstract

Among the functional, materials shape memory alloys are important because of their unique properties. So, these materials have attracted more attention to be used in micro/nano electronic and electromechanic systems. In this work, thermal evaporation method has been used to produce CuAlNi shape memory alloy thin film. The produced CuAlNi thin film has been characterized and the presence of the martensite phase was investigated and compared with the CuAlNi alloy sample. CuAlNi shape memory alloy thin film about 6.12 µm thick, showing a M→A transformation has been produced and also thermal and structural observations were made to analysis the shape memory behaviour of the Cu-Al-Ni shape memory thin films.

References

  • Canbay, C. A. (2010). The production of Cu-based shape memory alloys and investigation of microstructural, thermal and electrical properties of alloys, Ph. D Thesis, Fırat University, Institute of Science, Elazığ/Turkey (Turkish).
  • Gómez-Cortés, J., J. San Juan, G. López and M. Nó (2013). "Synthesis and characterization of Cu–Al–Ni shape memory alloy multilayer thin films." Thin Solid Films Vol. 544, No. pp. 588-592.
  • Izadinia, M. and K. Dehghani (2011). "Structure and properties of nanostructured Cu-13.2 Al-5.1 Ni shape memory alloy produced by melt spinning." Transactions of Nonferrous Metals Society of China Vol. 21, No. 9 pp. 2037-2043.
  • Karagoz, Z. and C. A. Canbay (2013). "Relationship between transformation temperatures and alloying elements in Cu–Al–Ni shape memory alloys." Journal of Thermal Analysis and Calorimetry Vol. 114, No. 3 pp. 1069-1074.
  • Kato, H., Y. Yasuda and K. Sasaki (2011). "Thermodynamic assessment of the stabilization effect in deformed shape memory alloy martensite." Acta Materialia Vol. 59, No. 10 pp. 3955-3964.
  • Kissinger, H. E. (1957). "Reaction kinetics in differential thermal analysis." Analytical chemistry Vol. 29, No. 11 pp. 1702-1706.
  • Lojen, G., I. Anžel, A. Kneissl, A. Križman, E. Unterweger, B. Kosec and M. Bizjak (2005). "Microstructure of rapidly solidified Cu–Al–Ni shape memory alloy ribbons." Journal of Materials Processing Technology Vol. 162, No. pp. 220-229.
  • Massad, J. E. and R. C. Smith (2005). "A homogenized free energy model for hysteresis in thin-film shape memory alloys." Thin Solid Films Vol. 489, No. 1 pp. 266-290.
  • Meng, Q., H. Yang, Y. Liu and T.-h. Nam (2010). "Transformation intervals and elastic strain energies of B2-B19 ′ martensitic transformation of NiTi." Intermetallics Vol. 18, No. 12 pp. 2431-2434.
  • Otsuka, K. and X. Ren (2005). "Physical metallurgy of Ti–Ni-based shape memory alloys." Progress in materials science Vol. 50, No. 5 pp. 511-678.
  • Otsuka, K. and C. Wayman (1998). "Mechanism of shape memory effect and superelasticity." Shape memory materials, No. pp. 27-48.
  • Ozawa, T. (1970). "Kinetic analysis of derivative curves in thermal analysis." Journal of Thermal Analysis and Calorimetry Vol. 2, No. 3 pp. 301-324.
  • Pérez-Landazábal, J. I., V. Recarte, V. Sánchez-Alarcos, M. L. Nó and J. S. Juan (2006). "Study of the stability and decomposition process of the β phase in Cu–Al–Ni shape memory alloys." Materials Science and Engineering: A Vol. 438–440, No. pp. 734-737.
  • Recarte, V., J. Perez-Landazabal, P. Rodrıguez, E. Bocanegra, M. No and J. San Juan (2004). "Thermodynamics of thermally induced martensitic transformations in Cu–Al–Ni shape memory alloys." Acta materialia Vol. 52, No. 13 pp. 3941-3948.
  • Sobrero, C., P. La Roca, A. Roatta, R. Bolmaro and J. Malarría (2012). "Shape memory properties of highly textured Cu–Al–Ni–(Ti) alloys." Materials Science and Engineering: A Vol. 536, No. pp. 207-215.
  • Wang, Z., X. Zu, H. Yu, X. He, C. Peng and Y. Huo (2006). "Temperature memory effect in CuAlNi single crystalline and CuZnAl polycrystalline shape memory alloys." Thermochimica acta Vol. 448, No. 1 pp. 69-72.
  • Xuan, Q., J. Bohong, T. Hsu and X. Zuyao (1987). "The effect of martensite ordering on shape memory effect in a copper-zinc-aluminium alloy." Materials Science and Engineering Vol. 93, No. pp. 205-211.
There are 17 citations in total.

Details

Primary Language English
Subjects Engineering
Journal Section Articles
Authors

Canan Aksu Canbay

Ayşe Tekataş This is me

İskender Özkul

Publication Date September 15, 2017
Published in Issue Year 2017 Volume: 1 Issue: 2

Cite

APA Canbay, C. A., Tekataş, A., & Özkul, İ. (2017). FABRICATION OF Cu-Al-Ni SHAPE MEMORY THIN FILM BY THERMAL EVAPORATION. Turkish Journal of Engineering, 1(2), 70-75. https://doi.org/10.31127/tuje.316254
AMA Canbay CA, Tekataş A, Özkul İ. FABRICATION OF Cu-Al-Ni SHAPE MEMORY THIN FILM BY THERMAL EVAPORATION. TUJE. September 2017;1(2):70-75. doi:10.31127/tuje.316254
Chicago Canbay, Canan Aksu, Ayşe Tekataş, and İskender Özkul. “FABRICATION OF Cu-Al-Ni SHAPE MEMORY THIN FILM BY THERMAL EVAPORATION”. Turkish Journal of Engineering 1, no. 2 (September 2017): 70-75. https://doi.org/10.31127/tuje.316254.
EndNote Canbay CA, Tekataş A, Özkul İ (September 1, 2017) FABRICATION OF Cu-Al-Ni SHAPE MEMORY THIN FILM BY THERMAL EVAPORATION. Turkish Journal of Engineering 1 2 70–75.
IEEE C. A. Canbay, A. Tekataş, and İ. Özkul, “FABRICATION OF Cu-Al-Ni SHAPE MEMORY THIN FILM BY THERMAL EVAPORATION”, TUJE, vol. 1, no. 2, pp. 70–75, 2017, doi: 10.31127/tuje.316254.
ISNAD Canbay, Canan Aksu et al. “FABRICATION OF Cu-Al-Ni SHAPE MEMORY THIN FILM BY THERMAL EVAPORATION”. Turkish Journal of Engineering 1/2 (September 2017), 70-75. https://doi.org/10.31127/tuje.316254.
JAMA Canbay CA, Tekataş A, Özkul İ. FABRICATION OF Cu-Al-Ni SHAPE MEMORY THIN FILM BY THERMAL EVAPORATION. TUJE. 2017;1:70–75.
MLA Canbay, Canan Aksu et al. “FABRICATION OF Cu-Al-Ni SHAPE MEMORY THIN FILM BY THERMAL EVAPORATION”. Turkish Journal of Engineering, vol. 1, no. 2, 2017, pp. 70-75, doi:10.31127/tuje.316254.
Vancouver Canbay CA, Tekataş A, Özkul İ. FABRICATION OF Cu-Al-Ni SHAPE MEMORY THIN FILM BY THERMAL EVAPORATION. TUJE. 2017;1(2):70-5.
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