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Influence of incorporated nanoparticles on superelastic behavior of shape memory alloys

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Autorschaft

  • Victor A. L'vov
  • Anna Kosogor
  • Serafima I. Palamarchuk
  • Gregory Gerstein
  • Hans J. Maier

Organisationseinheiten

Externe Organisationen

  • Kyiv National Taras Shevchenko University
  • Nationale Akademie der Wissenschaften der Ukraine

Details

OriginalspracheEnglisch
Aufsatznummer139025
FachzeitschriftMaterials Science and Engineering A
Jahrgang776
Frühes Online-Datum30 Jan. 2020
PublikationsstatusVeröffentlicht - 3 März 2020

Abstract

The internal elastic strain resulting from an ensemble of nanoparticles in the crystal lattice of a shape memory alloy (SMA) is introduced as a key parameter into a quantitative theory of superelastic behaviour of SMA-nanoparticle composites. Experimental stress−strain loops obtained for a Co-Ni-Ga-nanoparticle system are analysed and a good agreement between the experimental and theoretical results is demonstrated. It is shown that even small (≈10−3) internal strains can lead to profound differences in stress−strain response between SMA-nanoparticle composites and “particle-free” SMA. The internal strains can enlarge the attainable value of superelastic strain, will strengthen the crystal lattice of the SMA and can give rise to high-temperature superelasticity of SMA-nanoparticle composites. The theory predicts that the larger the volume change is during the MT, the more pronounced is the influence of the nanoparticles on the superelastic behaviour of SMA.

ASJC Scopus Sachgebiete

Zitieren

Influence of incorporated nanoparticles on superelastic behavior of shape memory alloys. / L'vov, Victor A.; Kosogor, Anna; Palamarchuk, Serafima I. et al.
in: Materials Science and Engineering A, Jahrgang 776, 139025, 03.03.2020.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

L'vov VA, Kosogor A, Palamarchuk SI, Gerstein G, Maier HJ. Influence of incorporated nanoparticles on superelastic behavior of shape memory alloys. Materials Science and Engineering A. 2020 Mär 3;776:139025. Epub 2020 Jan 30. doi: 10.1016/j.msea.2020.139025
L'vov, Victor A. ; Kosogor, Anna ; Palamarchuk, Serafima I. et al. / Influence of incorporated nanoparticles on superelastic behavior of shape memory alloys. in: Materials Science and Engineering A. 2020 ; Jahrgang 776.
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title = "Influence of incorporated nanoparticles on superelastic behavior of shape memory alloys",
abstract = "The internal elastic strain resulting from an ensemble of nanoparticles in the crystal lattice of a shape memory alloy (SMA) is introduced as a key parameter into a quantitative theory of superelastic behaviour of SMA-nanoparticle composites. Experimental stress−strain loops obtained for a Co-Ni-Ga-nanoparticle system are analysed and a good agreement between the experimental and theoretical results is demonstrated. It is shown that even small (≈10−3) internal strains can lead to profound differences in stress−strain response between SMA-nanoparticle composites and “particle-free” SMA. The internal strains can enlarge the attainable value of superelastic strain, will strengthen the crystal lattice of the SMA and can give rise to high-temperature superelasticity of SMA-nanoparticle composites. The theory predicts that the larger the volume change is during the MT, the more pronounced is the influence of the nanoparticles on the superelastic behaviour of SMA.",
keywords = "High-temperature superelasticity, Nanocomposite, Shape memory alloy, Strengthening, Thermomechanical treatment",
author = "L'vov, {Victor A.} and Anna Kosogor and Palamarchuk, {Serafima I.} and Gregory Gerstein and Maier, {Hans J.}",
note = "Funding information: This study was supported by the German Research Foundation [grant number 388671975 ], the National Academy of Sciences of Ukraine [grant number 0117U000433 ], and the Ministry of Education and Science Ukraine [grant number 19BF052-01 ].",
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Download

TY - JOUR

T1 - Influence of incorporated nanoparticles on superelastic behavior of shape memory alloys

AU - L'vov, Victor A.

AU - Kosogor, Anna

AU - Palamarchuk, Serafima I.

AU - Gerstein, Gregory

AU - Maier, Hans J.

N1 - Funding information: This study was supported by the German Research Foundation [grant number 388671975 ], the National Academy of Sciences of Ukraine [grant number 0117U000433 ], and the Ministry of Education and Science Ukraine [grant number 19BF052-01 ].

PY - 2020/3/3

Y1 - 2020/3/3

N2 - The internal elastic strain resulting from an ensemble of nanoparticles in the crystal lattice of a shape memory alloy (SMA) is introduced as a key parameter into a quantitative theory of superelastic behaviour of SMA-nanoparticle composites. Experimental stress−strain loops obtained for a Co-Ni-Ga-nanoparticle system are analysed and a good agreement between the experimental and theoretical results is demonstrated. It is shown that even small (≈10−3) internal strains can lead to profound differences in stress−strain response between SMA-nanoparticle composites and “particle-free” SMA. The internal strains can enlarge the attainable value of superelastic strain, will strengthen the crystal lattice of the SMA and can give rise to high-temperature superelasticity of SMA-nanoparticle composites. The theory predicts that the larger the volume change is during the MT, the more pronounced is the influence of the nanoparticles on the superelastic behaviour of SMA.

AB - The internal elastic strain resulting from an ensemble of nanoparticles in the crystal lattice of a shape memory alloy (SMA) is introduced as a key parameter into a quantitative theory of superelastic behaviour of SMA-nanoparticle composites. Experimental stress−strain loops obtained for a Co-Ni-Ga-nanoparticle system are analysed and a good agreement between the experimental and theoretical results is demonstrated. It is shown that even small (≈10−3) internal strains can lead to profound differences in stress−strain response between SMA-nanoparticle composites and “particle-free” SMA. The internal strains can enlarge the attainable value of superelastic strain, will strengthen the crystal lattice of the SMA and can give rise to high-temperature superelasticity of SMA-nanoparticle composites. The theory predicts that the larger the volume change is during the MT, the more pronounced is the influence of the nanoparticles on the superelastic behaviour of SMA.

KW - High-temperature superelasticity

KW - Nanocomposite

KW - Shape memory alloy

KW - Strengthening

KW - Thermomechanical treatment

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DO - 10.1016/j.msea.2020.139025

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VL - 776

JO - Materials Science and Engineering A

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