Enhancing surface strength of tungsten by gradient nano-grained structure

Daqian Xu, Zhifeng Huang, Like Xu, Guanchao Yin, Yaojun Lin, Qiang Shen, Fei Chen
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Abstract

A gradient nano-grained (GNG) structure demonstrates satisfactory surface strength. However, the underlying mechanism responsible for its strengthening lacks sufficient research. To explain how gradient nano-grained structures improve surface strength in detail, large-scale parallel molecular dynamics simulations are utilized in this study to investigate the mechanical deformation behavior of BCC tungsten with varying grain sizes during spherical nanoindentation. The findings suggest that a well-designed gradient structure can promote rational plasticity and an appropriate distribution of internal atomic stress. The critical point of maximum stress and hardness is observed when the initial grain size is 4.5 nm, with an average grain size of 7.1 nm. The interaction between grain boundary slip and migration in small grains, along with the enhanced activity of grain boundary dislocations in large grains, collectively contributes to the enhancement of the strength and hardness of the GNG structure. Compared with a homogeneous nano-grained structure, the gradient nano-grained structure exhibits a more rational distribution of dislocations and stress relaxation effects to enhance strength. The present work utilizes the molecular dynamics nanoindentation method to study GNG materials, providing a methodology for investigating the surface strengthening effects of GNG structures at the atomic scale and effectively revealing potential mechanisms for resisting surface deformation in GNG structures.
通过梯度纳米颗粒结构提高钨的表面强度
梯度纳米颗粒(GNG)结构具有令人满意的表面强度。然而,对其增强的内在机制却缺乏足够的研究。为了详细解释梯度纳米晶粒结构如何提高表面强度,本研究利用大规模并行分子动力学模拟,研究了不同晶粒大小的 BCC 钨在球形纳米压痕过程中的机械变形行为。研究结果表明,精心设计的梯度结构可以促进合理的塑性和内部原子应力的适当分布。当初始晶粒大小为 4.5 nm,平均晶粒大小为 7.1 nm 时,可观察到最大应力和硬度的临界点。小晶粒中晶界滑移和迁移之间的相互作用,以及大晶粒中晶界位错活动的增强,共同促成了 GNG 结构强度和硬度的提高。与均匀的纳米晶粒结构相比,梯度纳米晶粒结构的位错分布更合理,应力松弛效应更明显,从而提高了强度。本研究利用分子动力学纳米压痕方法研究 GNG 材料,为在原子尺度上研究 GNG 结构的表面强化效应提供了一种方法,并有效揭示了 GNG 结构抵抗表面变形的潜在机制。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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