Effect of Peierls stress and strain-hardening parameters on EMR emission in metals and alloys during progressive plastic deformation

Anmol Kothari; Vishal S. Chauhan; Amit Kumar; Rajeev Kumar; Rahul Vaish; Syed Abbas

doi:10.3139/146.111376

Article

Effect of Peierls stress and strain-hardening parameters on EMR emission in metals and alloys during progressive plastic deformation

Anmol Kothari , Vishal S. Chauhan , Amit Kumar , Rajeev Kumar , Rahul Vaish and Syed Abbas

Published/Copyright: June 5, 2016

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From the journal International Journal of Materials Research Volume 107 Issue 6

Abstract

The article deals with the development of a theoretical model to predict the nature (amplitude and shape) of deformation-induced electromagnetic radiation (EMR) in metals and alloys during progressive plastic deformation. The model explicitly embraces the effect of Peierls stress and strain hardening to envisage the nature of EMR in materials with relatively large Peierls stress. The theoretical results were evaluated for 0.15 % plain carbon steel and compared with experimental results. The signals obtained from the model were found to be exponential in shape and are in good agreement with the experimental observations. The results suggest that inclusion of strain hardening parameters in the earlier model is necessary for determining deformation induced EMR in bcc metals and alloys during progressive plastic deformation.

Keywords: Electromagnetic radiation; Peierls stress; Plastic deformation; Strain hardening; Laplace transform

*Correspondence address, Anmol Kothari, 102 Flour Daniel Building, Clemson University, Clemson, SC – 29634, USA, Tel.: +1 864 656-5638, E-mail: anmolk@clemson.edu

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Received: 2015-12-02

Accepted: 2016-02-18

Published Online: 2016-06-05

Published in Print: 2016-06-10

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Articles in the same Issue

https://doi.org/10.3139/146.111376

Keywords for this article

Electromagnetic radiation; Peierls stress; Plastic deformation; Strain hardening; Laplace transform