Meryem Taoufiki, Hanae Chabba, Hassane Mes-Adi, A. Barroug, A. Jouaiti
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引用次数: 0
Abstract
The strain rate exerts a profound influence on the mechanical characteristics of nanomaterials. To investigate this phenomenon, the molecular dynamics approach was employed to examine the impact of uniaxial compression along the [100] crystallographic direction in monocrystalline Al. The purpose of this research was to determine the differences in reactions observed during the elastic and plastic phases. It employed the Embedded Atom Method (EAM) as well as the Modified Embedded Atom Method (MEAM) potentials at 300 K. A comparative analysis of the outcomes from these potentials demonstrated considerable disparities. The results encompassed the percentage distribution of crystal structures (fcc, hcp, bcc, and others) as well as their atomic configurations. Several analytical factors were examined, including the strain-stress curve, the radial distribution function (RDF), the common neighbor analysis (CAN). The applied MEAM potential represents a subsequent occurrence of transitions following EAM, encompassing both increasing and decreasing phase transitions.
应变速率对纳米材料的机械特性有着深远的影响。为了研究这一现象,我们采用了分子动力学方法来研究单晶铝沿[100]晶体学方向单轴压缩的影响。这项研究的目的是确定在弹性阶段和塑性阶段观察到的反应差异。研究采用了嵌入式原子法(EAM)和修正嵌入式原子法(MEAM)在 300 K 时的电位。结果包括晶体结构(Fcc、HCP、BCC 和其他)的分布百分比及其原子构型。研究还考察了几个分析因素,包括应变应力曲线、径向分布函数(RDF)和共邻分析(CAN)。所应用的 MEAM 电位代表了 EAM 之后发生的转变,包括增加和减少的相变。
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