Vibration mitigation by the reversible fcc/hcp martensitic transformation during cyclic tension–compression loading of an Fe–Mn–Si-based shape memory alloy

Sawaguchi, Takahiro and Sahu, Puspendu and Kikuchi, Takehiko and Ogawa, Kazuyuki and Kajiwara, Setsuo and Kushibe, Atsumichi and Higashino, Masahiko and Ogawa, Takatoshi (2006) Vibration mitigation by the reversible fcc/hcp martensitic transformation during cyclic tension–compression loading of an Fe–Mn–Si-based shape memory alloy. Scripta Materialia, 54 (11). pp. 1885-1890.

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Abstract

The present work concerns the damping behavior of an Fe–28Mn–6Si–5Cr–0.5NbC (mass%) shape memory alloy determined by low cycle fatigue tests, and the corresponding deformation mechanism under cyclic tension–compression loading. The specific damping capacity increases with increasing strain amplitude and reaches saturation at 80%, above the strain amplitude of 0.4%. Quantitative X-ray diffraction analyses and microstructural observations using atomic force microscopy revealed that a significant amount of the tensile stress-induced ε martensite is reversely transformed into the austenite by subsequent compression; in other words, the stress-induced ‘reverse’ martensitic transformation takes place in the alloy.

Item Type:Article
Official URL/DOI:http://dx.doi.org/10.1016/j.scriptamat.2006.02.013
Uncontrolled Keywords:Low cycle fatigue; X-ray diffraction (XRD); Shape memory alloys (SMA); Martensitic phase transformation; Seismic damping
Divisions:Material Science and Technology
ID Code:222
Deposited By:INVALID USER
Deposited On:29 Oct 2009 11:36
Last Modified:09 Feb 2012 11:14
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