Damping mechanisms of Fe - Mn alloy with (γ + ε) dual phase structure

J. H. Jun; Y. K. Lee; C. S. Choi

doi:10.1179/026708300101507974

Damping mechanisms of Fe - Mn alloy with (γ + ε) dual phase structure

J. H. Jun, Y. K. Lee, C. S. Choi

Department of Materials Science and Engineering

Research output: Contribution to journal › Article › peer-review

16 Citations (Scopus)

Abstract

The objective of the present study is to propose damping mechanisms for Fe - Mn alloys containing austenite (face centred cubic) and ε martensite (hexagonal close packed), and to analyse the individual contribution of damping mechanisms to the total damping capacity of an Fe - 17 wt-%Mn alloy with respect to volume fraction of ε martensite. On the basis of substructural characteristics of γ and ε phases, it is suggested that damping mechanisms of Fe - Mn alloys with (γ + ε) dual phase structures involve stress induced movement of various boundaries such as stacking fault boundaries in austenite and ε martensite, ε martensite variant boundaries, and γ/ε interphase boundaries. The damping capacity of the Fe - 17Mn alloy increases with increasing ε martensite content. The quantitative analysis shows that in the as quenched state, the ε martensite phase is responsible for a major part of the damping capacity.

Original language	English
Pages (from-to)	389-392
Number of pages	4
Journal	Materials Science and Technology
Volume	16
Issue number	4
DOIs	https://doi.org/10.1179/026708300101507974
Publication status	Published - 2000

All Science Journal Classification (ASJC) codes

Materials Science(all)
Condensed Matter Physics
Mechanics of Materials
Mechanical Engineering

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abstract = "The objective of the present study is to propose damping mechanisms for Fe - Mn alloys containing austenite (face centred cubic) and ε martensite (hexagonal close packed), and to analyse the individual contribution of damping mechanisms to the total damping capacity of an Fe - 17 wt-%Mn alloy with respect to volume fraction of ε martensite. On the basis of substructural characteristics of γ and ε phases, it is suggested that damping mechanisms of Fe - Mn alloys with (γ + ε) dual phase structures involve stress induced movement of various boundaries such as stacking fault boundaries in austenite and ε martensite, ε martensite variant boundaries, and γ/ε interphase boundaries. The damping capacity of the Fe - 17Mn alloy increases with increasing ε martensite content. The quantitative analysis shows that in the as quenched state, the ε martensite phase is responsible for a major part of the damping capacity.",

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T1 - Damping mechanisms of Fe - Mn alloy with (γ + ε) dual phase structure

AU - Jun, J. H.

AU - Lee, Y. K.

AU - Choi, C. S.

PY - 2000

Y1 - 2000

N2 - The objective of the present study is to propose damping mechanisms for Fe - Mn alloys containing austenite (face centred cubic) and ε martensite (hexagonal close packed), and to analyse the individual contribution of damping mechanisms to the total damping capacity of an Fe - 17 wt-%Mn alloy with respect to volume fraction of ε martensite. On the basis of substructural characteristics of γ and ε phases, it is suggested that damping mechanisms of Fe - Mn alloys with (γ + ε) dual phase structures involve stress induced movement of various boundaries such as stacking fault boundaries in austenite and ε martensite, ε martensite variant boundaries, and γ/ε interphase boundaries. The damping capacity of the Fe - 17Mn alloy increases with increasing ε martensite content. The quantitative analysis shows that in the as quenched state, the ε martensite phase is responsible for a major part of the damping capacity.

AB - The objective of the present study is to propose damping mechanisms for Fe - Mn alloys containing austenite (face centred cubic) and ε martensite (hexagonal close packed), and to analyse the individual contribution of damping mechanisms to the total damping capacity of an Fe - 17 wt-%Mn alloy with respect to volume fraction of ε martensite. On the basis of substructural characteristics of γ and ε phases, it is suggested that damping mechanisms of Fe - Mn alloys with (γ + ε) dual phase structures involve stress induced movement of various boundaries such as stacking fault boundaries in austenite and ε martensite, ε martensite variant boundaries, and γ/ε interphase boundaries. The damping capacity of the Fe - 17Mn alloy increases with increasing ε martensite content. The quantitative analysis shows that in the as quenched state, the ε martensite phase is responsible for a major part of the damping capacity.

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Damping mechanisms of Fe - Mn alloy with (γ + ε) dual phase structure

Abstract

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