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Exploring the impact of pre-existing helium bubbles on nanoindentation in tungsten through molecular dynamics simulation

Authors :
Pan-dong Lin
Jun-feng Nie
Shu-gang Cui
Wen-dong Cui
Lei He
Gui-yong Xiao
Yu-peng Lu
Source :
Journal of Materials Research and Technology, Vol 31, Iss , Pp 2708-2722 (2024)
Publication Year :
2024
Publisher :
Elsevier, 2024.

Abstract

Gaining insight into the underlying mechanisms driving nanoindentation-induced behavior in tungsten is essential for comprehending its mechanical properties. Although the plasticity of conventional pure tungsten under nanocontact conditions is well understood, these theoretical constructs may become inadequate when applied to irradiated tungsten due to the interplay between helium bubbles and dislocations. Here, we employed an integrated approach, combining crystal defect theories, molecular dynamics simulations, and machine learning, to explore the initiation and progression of dislocations in tungsten containing helium bubbles during nanoindentation, focusing on elucidating the impact of helium bubbles. In contrast to the typical dislocation nucleation in pure tungsten, the presence of helium bubbles mitigates local shear strain, thereby hindering dislocation nucleation and propagation, leading to a reduction of indentation force. Additionally, we conducted a comparative analysis between samples with and without helium bubbles, examining factors such as atomic displacement, strain localization parameters, dislocation line length, and stress component distribution. More importantly, a significant outcome of our study is the establishment of a relationship between the consistent alteration in the shape of helium bubbles and their size during micro-scale nanoindentation, achieved through machine learning techniques. Our findings reveal that the area occupied by helium bubbles post-nanoindentation is inversely correlated with indentation depth and directly linked to helium bubble size. These discoveries represent a notable advancement in understanding the effects of irradiation to a certain degree.

Details

Language :
English
ISSN :
22387854
Volume :
31
Issue :
2708-2722
Database :
Directory of Open Access Journals
Journal :
Journal of Materials Research and Technology
Publication Type :
Academic Journal
Accession number :
edsdoj.919f4cd70df14e3da246f48740ee123d
Document Type :
article
Full Text :
https://doi.org/10.1016/j.jmrt.2024.06.222