Influence of IMC surface geometry and material properties on micro-bump reliability of 3D Chip-on-Chip interconnect technology

Ching-Feng Yu, Hsien-Chie Cheng, Y. Tsai, Su-Tsai Lu, Wen-Hwa Chen
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Abstract

This study aims at investigating the growth reaction of the Ni3Sn4 IMC during thermocompression bonding process, the anisotropic elastic constants of the IMC, and the effects of the material properties and surface geometry or morphology on the interconnect reliability of a three-dimensional (3D) Chip-on-Chip (CoC) interconnect technology with Cu/Ni/SnAg micro-bumps subject to accelerated thermal cycling (ATC) loading. The research starts from the investigation of the growth reaction of the Ni3Sn4 IMC during thermocompression bonding process through experiment and classical diffusion theory. The relationship between the Ni3Sn4 IMC thickness and bonding temperature/time is derived based on the predicted activation energy of the chemical reaction of the IMC layer by experiment. Next, the elastic stiffness coefficients of single crystal monoclinic Ni3Sn4 are calculated through molecular dynamics (MD) simulation using the polymer consistent force field (PCFF). The degree of anisotropy in the Ni3Sn4 crystal system is also confirmed by the electronic structure of single crystal Ni3Sn4 using first-principles calculation based on density function theory (DFT). For comparison with the published experimental data and also use in the subsequent reliability analysis, the effective elastic properties of polycrystalline Ni3Sn4 are derived using the Voigt-Reuss bound and Voigt-Reuss Hill average based on the calculated elastic stiffness coefficients. At last, 2D plane strain finite element (FE) analysis together with an empirical Coffin-Manson fatigue life prediction model are performed to predict the interconnect reliability of the 3D CoC interconnect technology. The computed results are compared with the ATC experimental data to demonstrate the effectiveness of these two FE models. The dependence of the interconnect reliability on the thickness, material properties and surface geometry or morphology of the Ni3Sn4 IMC is addressed.
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IMC表面几何形状和材料性能对三维片上互连技术微碰撞可靠性的影响
本研究旨在研究Ni3Sn4 IMC在热压键合过程中的生长反应,IMC的各向异性弹性常数,以及加速热循环(ATC)加载下具有Cu/Ni/SnAg微凸点的三维(3D) Chip-on-Chip (CoC)互连技术中材料性能和表面几何或形貌对互连可靠性的影响。本研究从热压键合过程中Ni3Sn4 IMC的生长反应入手,通过实验和经典扩散理论进行了研究。根据实验预测的IMC层化学反应活化能,导出了Ni3Sn4 IMC厚度与键合温度/时间的关系。其次,利用聚合物一致力场(PCFF)进行分子动力学(MD)模拟,计算单晶单斜Ni3Sn4的弹性刚度系数。利用基于密度泛函理论(DFT)的第一性原理计算,通过单晶Ni3Sn4的电子结构证实了Ni3Sn4晶体体系的各向异性程度。为了与已发表的实验数据进行比较,并用于后续的可靠性分析,基于计算得到的弹性刚度系数,采用Voigt-Reuss界和Voigt-Reuss Hill平均值推导了多晶Ni3Sn4的有效弹性性能。最后,通过二维平面应变有限元分析,结合Coffin-Manson疲劳寿命预测模型,对三维CoC互连技术的互连可靠性进行了预测。将计算结果与ATC实验数据进行了比较,验证了两种有限元模型的有效性。讨论了互连可靠性与Ni3Sn4 IMC的厚度、材料性能和表面几何或形貌的关系。
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