Microstructure and mechanical behavior of annealed MP35N alloy wire

In a previous paper, the microstructure, monotonic, and cyclic response of as-drawn ~100μm diameter MP35N low-Ti alloy wire were presented and discussed. In this sequel paper, the effects of annealing the same cold-drawn wire on microstructure and mechanical properties are examined. Specifically, se...

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Veröffentlicht in:	Materials science & engineering. A, Structural materials : properties, microstructure and processing Structural materials : properties, microstructure and processing, 2015-06, Vol.636, p.340-351
Hauptverfasser:	Prasad, M.J.N.V., Reiterer, M.W., Kumar, K.S.
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Sprache:	eng
Schlagworte:	Alloy wire Annealed Annealing Fatigue life Mechanical properties Medical devices Microstructure Nickel base alloys Recrystallization Recrystallized Texture Transmission electron microscopy Wire Yield strength
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description	In a previous paper, the microstructure, monotonic, and cyclic response of as-drawn ~100μm diameter MP35N low-Ti alloy wire were presented and discussed. In this sequel paper, the effects of annealing the same cold-drawn wire on microstructure and mechanical properties are examined. Specifically, segments of the wire were annealed for 1h at 973K, 1023K, 1073K, 1123K and 1173K in a vacuum furnace. The resulting microstructure was characterized by SEM, EBSD and TEM and compared to the as-drawn microstructure. In-situ heating in the TEM of MP35N ribbon in a similarly cold worked condition enabled corroboration of microstructure evolution during annealing. Annealed wires were tested monotonically and cyclically in uniaxial tension at room temperature, the latter using a stress ratio (R) of 0.3. In addition, the annealed wires were tested cyclically at R=−1 using the rotating beam bending fatigue test. Post-deformation structures and fracture surfaces were characterized using TEM and SEM respectively. Annealing the cold drawn wire results in recrystallization and grain growth; the extent is dependent on the annealing temperature. Deformation twin boundaries in the as-drawn structure illustrate faceted bulging and eventually complete elimination, the microstructure evolving into fine equiaxed grains containing coarser annealing twins with no significant change in texture. Yield strength decreases rapidly with recrystallization to almost half the value of the as-drawn condition, but is accompanied by an increase in modulus (by ~25%) and tensile elongation reaching ~30%. Cyclic response by the way of S–N curves is not enhanced by annealing on an absolute stress scale (due to the loss in yield strength) although the annealed wires are cyclically superior when the stress data are normalized by yield stress.
doi_str_mv	10.1016/j.msea.2015.03.103
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In this sequel paper, the effects of annealing the same cold-drawn wire on microstructure and mechanical properties are examined. Specifically, segments of the wire were annealed for 1h at 973K, 1023K, 1073K, 1123K and 1173K in a vacuum furnace. The resulting microstructure was characterized by SEM, EBSD and TEM and compared to the as-drawn microstructure. In-situ heating in the TEM of MP35N ribbon in a similarly cold worked condition enabled corroboration of microstructure evolution during annealing. Annealed wires were tested monotonically and cyclically in uniaxial tension at room temperature, the latter using a stress ratio (R) of 0.3. In addition, the annealed wires were tested cyclically at R=−1 using the rotating beam bending fatigue test. Post-deformation structures and fracture surfaces were characterized using TEM and SEM respectively. Annealing the cold drawn wire results in recrystallization and grain growth; the extent is dependent on the annealing temperature. Deformation twin boundaries in the as-drawn structure illustrate faceted bulging and eventually complete elimination, the microstructure evolving into fine equiaxed grains containing coarser annealing twins with no significant change in texture. Yield strength decreases rapidly with recrystallization to almost half the value of the as-drawn condition, but is accompanied by an increase in modulus (by ~25%) and tensile elongation reaching ~30%. 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A, Structural materials : properties, microstructure and processing</title><description>In a previous paper, the microstructure, monotonic, and cyclic response of as-drawn ~100μm diameter MP35N low-Ti alloy wire were presented and discussed. In this sequel paper, the effects of annealing the same cold-drawn wire on microstructure and mechanical properties are examined. Specifically, segments of the wire were annealed for 1h at 973K, 1023K, 1073K, 1123K and 1173K in a vacuum furnace. The resulting microstructure was characterized by SEM, EBSD and TEM and compared to the as-drawn microstructure. In-situ heating in the TEM of MP35N ribbon in a similarly cold worked condition enabled corroboration of microstructure evolution during annealing. Annealed wires were tested monotonically and cyclically in uniaxial tension at room temperature, the latter using a stress ratio (R) of 0.3. In addition, the annealed wires were tested cyclically at R=−1 using the rotating beam bending fatigue test. Post-deformation structures and fracture surfaces were characterized using TEM and SEM respectively. Annealing the cold drawn wire results in recrystallization and grain growth; the extent is dependent on the annealing temperature. Deformation twin boundaries in the as-drawn structure illustrate faceted bulging and eventually complete elimination, the microstructure evolving into fine equiaxed grains containing coarser annealing twins with no significant change in texture. Yield strength decreases rapidly with recrystallization to almost half the value of the as-drawn condition, but is accompanied by an increase in modulus (by ~25%) and tensile elongation reaching ~30%. 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A, Structural materials : properties, microstructure and processing</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Prasad, M.J.N.V.</au><au>Reiterer, M.W.</au><au>Kumar, K.S.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Microstructure and mechanical behavior of annealed MP35N alloy wire</atitle><jtitle>Materials science & engineering. A, Structural materials : properties, microstructure and processing</jtitle><date>2015-06-01</date><risdate>2015</risdate><volume>636</volume><spage>340</spage><epage>351</epage><pages>340-351</pages><issn>0921-5093</issn><eissn>1873-4936</eissn><abstract>In a previous paper, the microstructure, monotonic, and cyclic response of as-drawn ~100μm diameter MP35N low-Ti alloy wire were presented and discussed. In this sequel paper, the effects of annealing the same cold-drawn wire on microstructure and mechanical properties are examined. Specifically, segments of the wire were annealed for 1h at 973K, 1023K, 1073K, 1123K and 1173K in a vacuum furnace. The resulting microstructure was characterized by SEM, EBSD and TEM and compared to the as-drawn microstructure. In-situ heating in the TEM of MP35N ribbon in a similarly cold worked condition enabled corroboration of microstructure evolution during annealing. Annealed wires were tested monotonically and cyclically in uniaxial tension at room temperature, the latter using a stress ratio (R) of 0.3. In addition, the annealed wires were tested cyclically at R=−1 using the rotating beam bending fatigue test. Post-deformation structures and fracture surfaces were characterized using TEM and SEM respectively. Annealing the cold drawn wire results in recrystallization and grain growth; the extent is dependent on the annealing temperature. 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subjects	Alloy wire Annealed Annealing Fatigue life Mechanical properties Medical devices Microstructure Nickel base alloys Recrystallization Recrystallized Texture Transmission electron microscopy Wire Yield strength
title	Microstructure and mechanical behavior of annealed MP35N alloy wire
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