利用分子动力学研究压痕过程中 NiCrCoAl 中熵合金的纳米压痕行为

Thi-Thuy Binh Ngo, Van-Thuc Nguyen, Te-Hua Fang
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摘要

本研究利用分子动力学(MD)模拟探讨了 CoCrNiAl 中熵合金(MEA)在基体上受到压头刀尖压痕作用时的机械性能和变形行为。研究调查了合金成分、温度变化和超振动(UV)对总力、剪切应变、剪切应力、硬度、还原模量、基体温度、相变、位错长度和弹性恢复等参数的影响。研究结果表明,合金成分越高,总力、硬度和还原模量越大,其中富含镍的合金成分具有更高的机械强度。相反,合金成分的增加会导致冯米塞斯应力(VMS)、相变、位错分布和位错长度的减少,这是因为与其他主要元素相比,镍的原子尺寸更大。在基底温度升高的情况下,原子的振动幅度和原子间的分离度增大,导致原子结合力减弱,接触力降低,从而使基底在较高温度下变得更软。此外,较高的基底初始温度会增强原子动能和热振动,导致材料硬度降低和 VMS 水平升高。提高振动频率可扩大基底表面的压痕面积,使剪切应变和 VMS 随振动频率而集中。较高的振幅和频率会放大力、剪切应变、VMS、基底温度和位错分布。相反,振动振幅和频率越低,平均弹性恢复比越小。此外,振幅和频率值增大会产生以非晶体为主的压痕区域,并增加 HCP 和 BCC 结构的比例。此外,这项研究还考虑到了对材料在压痕过程中弹性恢复能力的评估,这是材料的一项基本特性。
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Study of nanoindentation behavior of NiCrCoAl medium entropy alloys under indentation process using molecular dynamics
The mechanical properties and deformation behavior of CoCrNiAl medium entropy alloy (MEA) subjected to indentation by an indenter tooltip on the substrate are explored using molecular dynamics (MD) simulation. The study investigates the effects of alloy compositions, temperature variations, and ultra vibration (UV) on parameters, such as total force, shear strain, shear stress, hardness, reduced modulus, substrate temperature, phase transformation, dislocation length, and elastic recovery. The findings indicate that higher alloy compositions result in increased total force, hardness, and reduced modulus, with Ni-rich compositions demonstrating superior mechanical strength. Conversely, increasing alloy compositions lead to reduced von Mises stress (VMS), phase transformation, dislocation distribution, and dislocation length due to the larger atomic size of Ni compared to other primary elements. At elevated substrate temperatures, atoms exhibit larger vibration amplitudes and interatomic separations, leading to weaker atomic bonding and decreased contact force, rendering the substrate softer at higher temperatures. Additionally, higher initial substrate temperatures enhance atom kinetic energy and thermal vibrations, leading to reduced material hardness and increased VMS levels. Increasing vibration frequency enlarges the indentation area on the substrate's surface, concentrating shear strain and VMS with vibration frequency. Higher vibration amplitude and frequency amplify force, shear strain, VMS, substrate temperature, and dislocation distribution. Conversely, lower vibration amplitude and frequency result in a smaller average elastic recovery ratio. Moreover, increased amplitude and frequency values yield an amorphous-dominated indentation region and increased proportions of HCP and BCC structures. Furthermore, this study also takes into account the evaluation of a material's ability to recover elastically during the indentation process, which is a fundamental material property.
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