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http://dx.doi.org/10.3795/KSME-A.2004.28.9.1306

A Material Simulation of High-Strain-Rate Deformation with Dislocations and Vacancies  

Choi, Deok-Kee (단국대학교 기계공학과)
Ryu, Han-Kyu (단국대학교 기계공학과 대학원)
Publication Information
Transactions of the Korean Society of Mechanical Engineers A / v.28, no.9, 2004 , pp. 1306-1313 More about this Journal
Abstract
This paper addresses a theoretical approach to calculate the amount of the stored energy during high strain-rate deformations using atomistic level simulation. The dynamic behavior of materials at high strain-rate deformation are of great interest. At high strain-rates deformations, materials generate heat due to plastic work and the temperature rise can be significant, affecting various properties of the material. It is well known that a small percent of the energy input is stored in the material, and most of input energy is converted into heat. However, microscopic analysis has not been completed without construction of a material model, which can simulate the movement of dislocations and vacancies. A major cause of the temperature rise within materials is traditionally credited to dislocations, vacancies and other defects. In this study, an atomistic material model for FCC such as copper is used to calculate the stored energy.
Keywords
Molecular Dynamics; Defects; Dislocation; Vacancy; Stored Energy; High-Strain-Rate Deformation;
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