Hysteresis and deformation mechanisms of transforming FeNiCoTi

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Externe Organisationen

  • University of Illinois Urbana-Champaign (UIUC)
  • Universität Paderborn
  • Tomsk State University
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Details

OriginalspracheEnglisch
Seiten (von - bis)538-550
Seitenumfang13
FachzeitschriftMechanics of materials
Jahrgang38
Ausgabenummer5-6
PublikationsstatusVeröffentlicht - Mai 2006
Extern publiziertJa

Abstract

We present an extensive set of experimental results on deformation behavior under external stress and thermal hysteresis behavior of FeNiCoTi shape memory alloys. The experiments spanned from temperatures where the martensite variant motion is responsible for shape changes to cases where stress-induced transformation from austenite to martensite occurred. A temperature hysteresis of the order of 130°C and recoverable strains approaching 3.5% were observed in these materials. These recoverable strain magnitudes far exceed previously reported values on FeNiCoTi alloys. We identify the role of increased slip resistance via aging as partially responsible for increased reversibility and increase in transformation strains. The relaxation of the stored energy due to presence of dislocations at austenite-martensite interfaces was identified with transmission electron microscopy studies, and this is the primary mechanism for large thermal hysteresis as well as the limiting factor in reversibility of the transformation. The changes in transformation temperatures and the hysteresis behavior in the presence of coherent precipitates were rationalized based on a thermodynamics based mechanics model.

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Hysteresis and deformation mechanisms of transforming FeNiCoTi. / Sehitoglu, Huseyin; Efstathiou, C.; Maier, H. J. et al.
in: Mechanics of materials, Jahrgang 38, Nr. 5-6, 05.2006, S. 538-550.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Sehitoglu H, Efstathiou C, Maier HJ, Chumlyakov Y. Hysteresis and deformation mechanisms of transforming FeNiCoTi. Mechanics of materials. 2006 Mai;38(5-6):538-550. doi: 10.1016/j.mechmat.2005.05.024
Sehitoglu, Huseyin ; Efstathiou, C. ; Maier, H. J. et al. / Hysteresis and deformation mechanisms of transforming FeNiCoTi. in: Mechanics of materials. 2006 ; Jahrgang 38, Nr. 5-6. S. 538-550.
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abstract = "We present an extensive set of experimental results on deformation behavior under external stress and thermal hysteresis behavior of FeNiCoTi shape memory alloys. The experiments spanned from temperatures where the martensite variant motion is responsible for shape changes to cases where stress-induced transformation from austenite to martensite occurred. A temperature hysteresis of the order of 130°C and recoverable strains approaching 3.5% were observed in these materials. These recoverable strain magnitudes far exceed previously reported values on FeNiCoTi alloys. We identify the role of increased slip resistance via aging as partially responsible for increased reversibility and increase in transformation strains. The relaxation of the stored energy due to presence of dislocations at austenite-martensite interfaces was identified with transmission electron microscopy studies, and this is the primary mechanism for large thermal hysteresis as well as the limiting factor in reversibility of the transformation. The changes in transformation temperatures and the hysteresis behavior in the presence of coherent precipitates were rationalized based on a thermodynamics based mechanics model.",
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AU - Sehitoglu, Huseyin

AU - Efstathiou, C.

AU - Maier, H. J.

AU - Chumlyakov, Y.

N1 - Funding Information: The work is supported by the Air Force Office of Scientific Research, Arlington, Virginia, Directorate of Aerospace and Materials Sciences. Prof. Chumlyakov’s work is supported by a Russian grant RFBR-02-03-32013.

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N2 - We present an extensive set of experimental results on deformation behavior under external stress and thermal hysteresis behavior of FeNiCoTi shape memory alloys. The experiments spanned from temperatures where the martensite variant motion is responsible for shape changes to cases where stress-induced transformation from austenite to martensite occurred. A temperature hysteresis of the order of 130°C and recoverable strains approaching 3.5% were observed in these materials. These recoverable strain magnitudes far exceed previously reported values on FeNiCoTi alloys. We identify the role of increased slip resistance via aging as partially responsible for increased reversibility and increase in transformation strains. The relaxation of the stored energy due to presence of dislocations at austenite-martensite interfaces was identified with transmission electron microscopy studies, and this is the primary mechanism for large thermal hysteresis as well as the limiting factor in reversibility of the transformation. The changes in transformation temperatures and the hysteresis behavior in the presence of coherent precipitates were rationalized based on a thermodynamics based mechanics model.

AB - We present an extensive set of experimental results on deformation behavior under external stress and thermal hysteresis behavior of FeNiCoTi shape memory alloys. The experiments spanned from temperatures where the martensite variant motion is responsible for shape changes to cases where stress-induced transformation from austenite to martensite occurred. A temperature hysteresis of the order of 130°C and recoverable strains approaching 3.5% were observed in these materials. These recoverable strain magnitudes far exceed previously reported values on FeNiCoTi alloys. We identify the role of increased slip resistance via aging as partially responsible for increased reversibility and increase in transformation strains. The relaxation of the stored energy due to presence of dislocations at austenite-martensite interfaces was identified with transmission electron microscopy studies, and this is the primary mechanism for large thermal hysteresis as well as the limiting factor in reversibility of the transformation. The changes in transformation temperatures and the hysteresis behavior in the presence of coherent precipitates were rationalized based on a thermodynamics based mechanics model.

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KW - Ferromagnetic shape memory alloy

KW - Hysteresis

KW - Iron-based shape memory alloy

KW - Martensite

KW - Modeling

KW - Phase transformation

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