Determining the threshold displacement energy of magnesium using molecular dynamics simulations

Authors

Tanu Pittie, Indian Institute of Technology Delhi
Gautam Kunwar, Indian Institute of Technology Delhi
Sumanta Das, University of Rhode Island
Jayant Jain, Indian Institute of Technology Delhi
Krishnan N M Anoop, Indian Institute of Technology Delhi

Document Type

Article

Date of Original Version

9-1-2022

Abstract

Despite its potential use as a lightweight material, the effects of irradiation on magnesium (Mg) remain poorly understood. Specifically, the threshold displacement energy (TDE), which corresponds to the minimum energy required to displace an atom from the lattice position has not been explored so far. Here, using molecular simulations, we estimate the TDE of an Mg single crystal. We observe that the TDE is not significantly affected by the location of an atom in the lattice and the incident direction of energy or collision. We also demonstrate the formation of local defects, which are instantly annealed. Interestingly, the annealing process is facilitated by the temporary displacement of atoms from their lattice position into the interstitials, which in turn results in the creation of at least one stable Frenkel pair defect. Overall, this study provides insights into the response of Mg crystal to radiation, which is crucial for development of Mg-based structures for applications in aerospace and nuclear industries.

Publication Title, e.g., Journal

Bulletin of Materials Science

Volume

45

Issue

3

Citation/Publisher Attribution

Pittie, Tanu, Gautam Kunwar, Sumanta Das, Jayant Jain, and Krishnan N M Anoop. "Determining the threshold displacement energy of magnesium using molecular dynamics simulations." Bulletin of Materials Science 45, 3 (2022). doi: 10.1007/s12034-022-02737-x.