Micro-scale plasticity effects in microvia reliability analysis

52nd Electronic Components and Technology Conference 2002. (Cat. No.02CH37345) Pub Date : 2002-08-07 DOI:10.1109/ECTC.2002.1008274

G. Ramakrishna, R. Pucha, S. Sitaraman

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引用次数: 7

Abstract

Microvias play a key role in high density wiring substrates. To theoretically predict the fatigue life of the microvias, accurate estimation of plastic strain evolution in microvias is critical. Due to the temperature-dependent material properties and high cyclic strains induced due to thermal excursions in electronic packaging interconnects and components, plasticity theories are extensively used to predict the low-cycle fatigue life. Experimental evidence indicates that plastic deformation in metals and polymers at small scales depends not only on the state variables of stress and strain, but also on their higher order gradients. As the diameter of the microvia reduces, the wall thickness correspondingly reduces and hence the minimum feature size reduces to the order of microns, where scale effects in plasticity are predominant. A plastic strain gradient-based computational algorithm is employed in this work to study the thermo-mechanical deformation of microvia structure. The thermo-mechanical reliability analysis demonstrates the influence of incorporating strain gradient effects in predicting the evolution of plastic deformation in microvia structures.

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微孔可靠性分析中的微尺度塑性效应

微过孔在高密度布线基板中起着关键作用。为了从理论上预测微孔的疲劳寿命，准确估计微孔内的塑性应变演化是至关重要的。由于材料的温度依赖性和电子封装互连和元件的热漂移引起的高循环应变，塑性理论被广泛用于预测低周疲劳寿命。实验结果表明，金属和聚合物在小尺度下的塑性变形不仅取决于应力和应变的状态变量，而且取决于它们的高阶梯度。随着微孔直径的减小，壁厚相应减小，因此最小特征尺寸减小到微米量级，塑性中的尺度效应占主导地位。本文采用基于塑性应变梯度的计算算法研究微孔结构的热机械变形。热-机械可靠性分析表明，考虑应变梯度效应对预测微孔结构塑性变形演化的影响。

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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52nd Electronic Components and Technology Conference 2002. (Cat. No.02CH37345)

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