Strain Rate Sensitivities of Face-Centred-Cubic Metals Using Molecular Dynamics Simulation
QIN Kun1,2, YANG Li-Ming2, HU Shi-Sheng1
1CAS Key Laboratory of Mechanical Behavior and Design of Materials, University of Science and Technology of China, Hefei 2300272Mechanics and Materials Science Research Centre, Faculty of Engineering, Ningbo University, Ningbo 315211
Strain Rate Sensitivities of Face-Centred-Cubic Metals Using Molecular Dynamics Simulation
QIN Kun1,2, YANG Li-Ming2, HU Shi-Sheng1
1CAS Key Laboratory of Mechanical Behavior and Design of Materials, University of Science and Technology of China, Hefei 2300272Mechanics and Materials Science Research Centre, Faculty of Engineering, Ningbo University, Ningbo 315211
摘要 We use dislocation theory and molecular dynamics (MD) simulations to investigate the effect of atom properties on the macroscopic strain rate sensitivity of fcc metals. A method to analyse such effect is proposed. The stress dependence of dislocation velocity is identified as the key of such study and is obtained via 2-D MD simulations on the motion of an individual dislocation in an fcc metal. Combining the simulation results with Orowan's relationship, it is concluded that strain rate sensitivities of fcc metals are mainly dependent on their atomic mass rather than the interatomic potential. The order of strain rate sensitivities of five fcc metals obtained by analysing is consistent with the experimental results available.
Abstract: We use dislocation theory and molecular dynamics (MD) simulations to investigate the effect of atom properties on the macroscopic strain rate sensitivity of fcc metals. A method to analyse such effect is proposed. The stress dependence of dislocation velocity is identified as the key of such study and is obtained via 2-D MD simulations on the motion of an individual dislocation in an fcc metal. Combining the simulation results with Orowan's relationship, it is concluded that strain rate sensitivities of fcc metals are mainly dependent on their atomic mass rather than the interatomic potential. The order of strain rate sensitivities of five fcc metals obtained by analysing is consistent with the experimental results available.
2008, Vol. 25 
