Impact of Nano Crack and Loading Direction on the Tensile Features of FeCr Alloy:A Molecular Dynamics Analysis

IF 3.1 Q2 MATERIALS SCIENCE, COMPOSITES
G. S, T. Jagadeesha
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引用次数: 0

Abstract

The existence of cracks and variations in loading direction has invoked greater modifications in the material properties. In this work, the tensile features of cracked and non-cracked FeCr polycrystals have been analyzed under numerous temperatures (300 K, 500 K, 700 K, and 900 K) and loading directions (parallel and normal to the crack cross-sectional directions) through molecular dynamics and it is originated that temperature has raised a higher impact on the tensile features trailed by the existence of crack and loading directions, owing to the formation of larger kinetic energy amidst the atoms. The existence of crack offers a moderate impression on the tensile behavior followed by the loading direction, due to its dominant impact on the tensile behavior through greater stress concentrations. Additionally, it is stated that the greater temperature along with the existence of crack and loading along normal to the crack cross section offers greater reductions in the tensile features of FeCr polycrystal, owed to the interactive effect of larger kinetic energy and discontinuity among atoms. Furthermore, the shear strain and displacement contour map and materials feature also confirm a similar occurrence which leads to altering its material behavior.
纳米裂纹和加载方向对铁铬合金拉伸特征的影响:分子动力学分析
裂纹的存在和加载方向的变化使材料特性发生了更大的变化。本研究通过分子动力学分析了在不同温度(300 K、500 K、700 K 和 900 K)和加载方向(平行于裂纹横截面方向和法线方向)下,有裂纹和无裂纹铁铬多晶体的拉伸特性,结果表明,温度对拉伸特性的影响较大,其次是裂纹的存在和加载方向,原因是原子之间形成了较大的动能。裂纹的存在对拉伸行为的影响不大,其次是加载方向,这是因为它通过更大的应力集中对拉伸行为产生了主导影响。此外,由于较大的动能和原子间不连续性的交互作用,温度升高、裂纹的存在以及沿裂纹横截面法线方向的加载对铁铬多晶的拉伸特性有较大的影响。此外,剪切应变和位移等值线图以及材料特征也证实了类似情况的发生,从而改变了其材料行为。
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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来源期刊
Functional Composites and Structures
Functional Composites and Structures Materials Science-Materials Science (miscellaneous)
CiteScore
4.80
自引率
10.70%
发文量
33
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