Hysteretic Behavior of Ferroelasticity of NiTi in Shear
Identifieur interne : 009968 ( Main/Exploration ); précédent : 009967; suivant : 009969Hysteretic Behavior of Ferroelasticity of NiTi in Shear
Auteurs : Yinong Liu [Australie] ; D. Favier ; L. Orgeas [France]Source :
- Journal of intelligent material systems and structures [ 1045-389X ] ; 2006-12.
Descripteurs français
- Wicri :
- topic : Alliage.
English descriptors
- KwdEn :
- Alloy, Apparent strain, Apparent strain level, Critical stress, Cycling, Deformation, Deformation process, Dissipation, Energy dissipation, External stress, Ferroelastic, Ferroelastic behavior, Ferroelastic cycle, Ferroelastic cycling, Ferroelastic deformation, Ferroelastic loop, Ferroelastic loops, Frictional resistance, Hysteresis, Hysteresis curves, Hysteresis loop, Hysteretic, Hysteretic behavior, Internal plastic deformation, Major loop, Martensite, Martensite reorientation, Martensite variants, Martensitic, Martensitic transformation, Matrix, Matrix resistance, Mechanical hysteresis, Minor loops, Miyazaki, Niti, Niti shape memory alloy, Niti shape memory alloys, Plastic deformation, Polycrystalline matrix, Reorientation, Shape change, Shape memory alloys, Shear strain, Shear stress, Strain span, Stress hysteresis, Testing temperature, Total strain, Twin boundaries, Twin boundary movement.
- Teeft :
- Alloy, Apparent strain, Apparent strain level, Critical stress, Cycling, Deformation, Deformation process, Dissipation, Energy dissipation, External stress, Ferroelastic, Ferroelastic behavior, Ferroelastic cycle, Ferroelastic cycling, Ferroelastic deformation, Ferroelastic loop, Ferroelastic loops, Frictional resistance, Hysteresis, Hysteresis curves, Hysteresis loop, Hysteretic, Hysteretic behavior, Internal plastic deformation, Major loop, Martensite, Martensite reorientation, Martensite variants, Martensitic, Martensitic transformation, Matrix, Matrix resistance, Mechanical hysteresis, Minor loops, Miyazaki, Niti, Niti shape memory alloy, Niti shape memory alloys, Plastic deformation, Polycrystalline matrix, Reorientation, Shape change, Shape memory alloys, Shear strain, Shear stress, Strain span, Stress hysteresis, Testing temperature, Total strain, Twin boundaries, Twin boundary movement.
Abstract
In the present work, the hysteretic behavior of ferroelastic deformation via martensite variant reorientation in a Ti–50.15 at.% Ni alloy is studied with cycling in shear. The stress hysteresis and the irreversible work dissipated during a cycle are found to decrease with cycling. The stress hysteresis is found to be dependent on the strain span of the loop but to be independent of the apparent strain about which the loop is performed. The mechanical hysteresis is attributed to two contributions: frictional resistance to twin boundary movement and matrix resistance to shape change of polycrystalline matrices.
Url:
DOI: 10.1177/1045389X06065237
Affiliations:
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Le document en format XML
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<term>Apparent strain level</term>
<term>Critical stress</term>
<term>Cycling</term>
<term>Deformation</term>
<term>Deformation process</term>
<term>Dissipation</term>
<term>Energy dissipation</term>
<term>External stress</term>
<term>Ferroelastic</term>
<term>Ferroelastic behavior</term>
<term>Ferroelastic cycle</term>
<term>Ferroelastic cycling</term>
<term>Ferroelastic deformation</term>
<term>Ferroelastic loop</term>
<term>Ferroelastic loops</term>
<term>Frictional resistance</term>
<term>Hysteresis</term>
<term>Hysteresis curves</term>
<term>Hysteresis loop</term>
<term>Hysteretic</term>
<term>Hysteretic behavior</term>
<term>Internal plastic deformation</term>
<term>Major loop</term>
<term>Martensite</term>
<term>Martensite reorientation</term>
<term>Martensite variants</term>
<term>Martensitic</term>
<term>Martensitic transformation</term>
<term>Matrix</term>
<term>Matrix resistance</term>
<term>Mechanical hysteresis</term>
<term>Minor loops</term>
<term>Miyazaki</term>
<term>Niti</term>
<term>Niti shape memory alloy</term>
<term>Niti shape memory alloys</term>
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<term>Polycrystalline matrix</term>
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<term>Shape memory alloys</term>
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<term>Hysteresis curves</term>
<term>Hysteresis loop</term>
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<term>Hysteretic behavior</term>
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<term>Major loop</term>
<term>Martensite</term>
<term>Martensite reorientation</term>
<term>Martensite variants</term>
<term>Martensitic</term>
<term>Martensitic transformation</term>
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<term>Matrix resistance</term>
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<term>Miyazaki</term>
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<term>Testing temperature</term>
<term>Total strain</term>
<term>Twin boundaries</term>
<term>Twin boundary movement</term>
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<front><div type="abstract" xml:lang="en">In the present work, the hysteretic behavior of ferroelastic deformation via martensite variant reorientation in a Ti–50.15 at.% Ni alloy is studied with cycling in shear. The stress hysteresis and the irreversible work dissipated during a cycle are found to decrease with cycling. The stress hysteresis is found to be dependent on the strain span of the loop but to be independent of the apparent strain about which the loop is performed. The mechanical hysteresis is attributed to two contributions: frictional resistance to twin boundary movement and matrix resistance to shape change of polycrystalline matrices.</div>
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