基于分子动力学模拟的环氧树脂材料性能预测

H. Fan, C. Wong, M. Yuen
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引用次数: 11

摘要

环氧树脂在电子封装中应用广泛,其性能对电子封装的可靠性起着至关重要的作用。对环氧树脂材料的力学性能有一个基本的了解,是指导高可靠性环氧树脂试验设计的必要条件。分子模型的应用非常广泛,并已被用于研究聚合物在分子水平上的力学性能,包括Tg的研究。本文主要研究了固化环氧树脂的材料性能。采用非晶模建立了环氧树脂的MD模型。在温度为225℃、压力为0.1Mpa的条件下,采用恒定粒子数、恒定压力和恒定温度(NPT)进行了分子动力学模拟。温度以10℃/200ps的速率降至室温。每个后续的模拟都是从在前一个温度下得到的最终构型开始的。在所有模拟中,非键相互作用的截止距离为1.5 nm,具有光滑的开关函数。每个案例研究中的模拟在每个MD模拟步骤中以1飞秒(fs)的间隔进行。根据平均比容计算各温度下环氧树脂的密度。根据密度-温度曲线斜率的不连续来估计Tg。根据体积与温度的变化关系,得到了体积热膨胀系数。可以计算出相应的环氧树脂的线性热膨胀系数。通过MD模拟可以得到环氧树脂的杨氏模量和泊松比。这些力学性能的预测值与实验值接近
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Prediction of Material Properties of Epoxy Materials using Molecular Dynamic Simulation
Epoxy is widely used in electronic packaging and its performance is very important to the reliability of electronic packages. It is necessary to understand the mechanical properties of epoxy materials at a fundamental level as a guide in the experimental design of epoxy resin for high reliability. Molecular modeling is widespread in its usage and has been used to investigate the mechanical properties of polymer at the molecular level, including the investigation of the Tg. The present study is focused on the material properties of the cured epoxy resin. MD model of the epoxy was built using the amorphous module. MD simulations were carried out starting at 225degC under a pressure of 0.1Mpa using the ensembles of the constant number of particles, constant-pressure and constant temperature (NPT). Temperature was lowered to room temperature at a rate of 10 degC/200ps. Each subsequent simulation was started from the final configuration obtained at the preceding temperature. Non-bond interactions cut-off distance of 1.5 nm with a smooth switching function was used in all simulations. The simulation in each case study was performed with an interval of 1 femto second (fs) in each MD simulation step. Density of the epoxy at each temperature was calculated from the average specific volume. Tg was estimated based on the discontinuity in the slope of the density-temperature plot. The volumetric thermal expansion coefficient was obtained from the relation of the variation of the volume and temperature. The corresponding linear thermal expansion coefficient of the epoxy can be calculated. Young's modulus and Poisson's ratio of the epoxy can also be obtained from MD simulations. The predicted values of these mechanical properties are close to the experimental values
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