焊盘结构下ULK在Cu线焊过程中的损伤与断裂模拟

Kritika Upreti, Hung-Yun Lin, G. Subbarayan, D. Jung, B. Sammakia
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引用次数: 5

摘要

多孔、低介电常数层间介电材料(ILD)的发展趋势对介电材料的机械完整性提出了挑战。因此,装配过程或切割过程引起的ILD堆叠断裂是一个重要的可靠性考虑因素。一般来说,有必要评估结构在装配条件下的断裂倾向,或设计裂纹止裂特征,以防止裂纹扩展到活动区域。对于线键合封装,由于冲击载荷和传递到ILD堆栈的高超声能量,超低k (ULK)电介质在有源电路(BOAC)上键合时断裂的可靠性问题是一个重大挑战。本文提出了一种多层建模方法来评估焊接过程中焊接层的断裂风险。首先,建立了非线性动态有限元模型,模拟了超声振动过程的冲击阶段和最后一个周期,研究了铜线键合过程中球、焊盘和焊盘下ULK的力学响应。在此基础上,提出了一种基于丰富等几何近似的仿真框架,利用内聚损伤描述来计算ULK堆的损伤累积。模拟框架用于深入了解ILD堆栈中潜在的裂纹起裂位置,并评估每个工艺步骤中的断裂风险。
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Simulations of damage and fracture in ULK under pad structures during Cu wirebond process
Mechanical integrity of the dielectric stack is challenged by the trend towards porous, lower dielectric constant interlayer dielectric (ILD) materials. As a result, fracture in the ILD stacks caused either by assembly process or by the dicing process is an important reliability consideration. In general, there is a need to either assess the propensity of the structure to fracture under assembly conditions, or to design crack-arrest features that prevent propagation of cracks into active areas. In the case of wire bonded packages, the reliability concern associated with the fracture of Ultra Low-k (ULK) dielectrics while bonding over the active circuits (BOAC) is a significant challenge due to the impact load and the high ultrasonic energy transmitted to the ILD stack. In this paper, a multi-level modeling procedure is presented to assess the risk of fracture in ILD stacks during wire bonding process. First, a nonlinear, dynamic finite element model is developed to simulate the process steps - impact stage and last cycle of ultrasonic vibration and study the mechanical response of the ball, pad, and the underlying ULK under pad during copper wire bonding. Further, a simulation framework based on enriched isogeometric approximations is presented to compute damage accumulation in the ULK stacks using a cohesive damage description. The simulation framework is employed to develop insights on the potential crack initiation sites within the ILD stack and to evaluate the risk of fracture during each process step.
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