Study on the Effect of Different Factors of Displacement Cascades in Alpha-Fe by Molecular Dynamics Simulations

核工程研究与设计 Pub Date : 2020-08-04 DOI:10.1115/icone2020-16161

P. Lin, J. Nie, Meidan Liu

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Abstract

As the key component of RPV steel, α-Fe is under neutron irradiation during its long-term service, and lattice atoms of α-Fe are knocked by neutrons, which leads to irradiation damage. In this paper, molecular dynamics method is conducted to investigate the effect of temperature, vacancy concentration and tensile strain on irradiation-induced damage by displacement cascade simulations in α-Fe. The simulations are performed with primary knock-on atom energies ranging from 0.1 to 5 keV, temperature ranging from 100 to 500K, vacancy concentration ranging from 0% to 1% and applied tensile strain ranging from 0 to 5%. The time evolution of defects produced during displacement cascade can be obtained where the surviving number of Frenkel pairs increases rapidly at first, then decrease and comes to stability finally. The influence of these factors on defect production can be concluded as following: The increase of PKA energy, vacancy concentration and applied tensile strain can lead to the increase of defect numbers. In contrast, the increase of temperature decreases the defect numbers. Vacancies and interstitials cluster size distributions are varied in different case. The results are meaningful to describe some microcosmic mechanisms of RPV steels in nuclear system.

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分子动力学模拟研究α - fe中不同因素对位移级联的影响

α-Fe作为RPV钢的关键成分，在长期使用过程中受到中子辐照，α-Fe晶格原子被中子撞击，导致辐照损伤。本文采用分子动力学方法，通过α-Fe中位移级联模拟，研究温度、空位浓度和拉伸应变对辐照损伤的影响。模拟的条件为:初级撞击原子能量为0.1 ~ 5kev，温度为100 ~ 500K，空位浓度为0% ~ 1%，外加拉伸应变为0 ~ 5%。可以得到位移级联过程中缺陷产生的时间演化规律，在此过程中，Frenkel对的存活数先迅速增加，然后逐渐减少，最后趋于稳定。这些因素对缺陷产生的影响如下:PKA能量、空位浓度和外加拉伸应变的增加会导致缺陷数量的增加。相反，温度的升高使缺陷数减少。空位和间隙的簇大小分布在不同的情况下是不同的。研究结果对描述核体系中RPV钢的一些微观机理具有重要意义。

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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核工程研究与设计

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