Issue 66, 2020, Issue in Progress

A molecular dynamics study on the mechanical properties of Fe–Ni alloy nanowires and their temperature dependence

Abstract

Fe–Ni alloy nanowires are widely used in high-density magnetic memories and catalysts due to their unique magnetic and electrochemical properties. Understanding the deformation mechanism and mechanical property of Fe–Ni alloy nanowires is of great importance for the development of devices. However, the detailed deformation mechanism of the alloy nanowires at different temperatures is unclear. Herein, the deformation mechanism of Fe–Ni alloy nanowires and their mechanical properties were investigated via the molecular dynamics simulation method. It was found that the local atomic pressure fluctuation of the Fe–Ni alloy nanowire surface became more prominent with an increase in the Ni content. At low temperature conditions (<50 K), the plastic deformation mechanism of the Fe–Ni alloy nanowires switched from the twinning mechanism to the dislocation slip mechanism with the increase in the Ni content from 0.5 at% to 8.0 at%. In the temperature range of 50–800 K, the dislocation slip mechanism dominated the deformation. Simulation results indicated that there was a significant linear relationship between the Ni content, temperature, and ultimate stress in the temperature range of 50–800 K. Our research revealed the association between the deformation mechanism and temperature in Fe–Ni alloy nanowires, which may facilitate new alloy nanowire designs.

Graphical abstract: A molecular dynamics study on the mechanical properties of Fe–Ni alloy nanowires and their temperature dependence

Article information

Article type
Paper
Submitted
13 Sep 2020
Accepted
19 Oct 2020
First published
03 Nov 2020
This article is Open Access
Creative Commons BY license

RSC Adv., 2020,10, 40084-40091

A molecular dynamics study on the mechanical properties of Fe–Ni alloy nanowires and their temperature dependence

J. Chen, P. Li and E. E. Lin, RSC Adv., 2020, 10, 40084 DOI: 10.1039/D0RA07831J

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