The current formulation of stress- and energy-based cohesive zone model (CZM) is extended to account for load reversals. Cyclic degradation of solder/IMC interface properties, namely penalty stiffness, strengths and critical energy release rates follows power-law functions of fatigue cycles. Performance of the extended CZM is examined using finite element (FE) simulation of a single Sn-4Ag-0.5Cu (SAC405) solder interconnect specimen. Strain rate-dependent response of the solder is represented by unified inelastic strain equations (Anand's model) with optimized model parameters for SAC405 solders. The 3D FE model of the specimen is subjected to cyclic relative displacement (Δδ = 0.003 mm, R = 0) so as to induce shear-dominant fatigue loading. Results show that interface crack initiated at the leading edge of the solder/IMC interface on the tool side of the assembly after 22 cycles have elapsed. Bending stress component induced by the solder stand-off height dominates the interface damage process. A straight interface crack front is predicted indicating the relatively brittle nature of the SAC405/Cu6Sn5 interface. The extended formulation of the CZM to account for load reversals has demonstrated the ability to describe the progressive solder/IMC interface damage process consistent with the mechanics of relatively brittle interface fracture.
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机译:基于应力和能量的内聚区模型(CZM)的当前公式已得到扩展,可以解决负载逆转问题。焊料/ IMC界面特性的循环退化,即惩罚刚度,强度和临界能量释放速率,遵循疲劳循环的幂律函数。使用单个Sn-4Ag-0.5Cu(SAC405)焊料互连标本的有限元(FE)模拟来检查扩展CZM的性能。焊料的应变速率相关响应由统一的非弹性应变方程式(Anand模型)表示,具有针对SAC405焊料的优化模型参数。样品的3D FE模型受到循环相对位移(Δδ= 0.003 mm,R = 0),以引起剪切为主的疲劳载荷。结果表明,经过22个循环后,界面裂纹从组件工具侧的焊料/ IMC界面的前沿开始。焊料支撑高度引起的弯曲应力分量在界面损坏过程中占主导地位。预计会出现一个平直的界面裂纹前沿,表明SAC405 / Cu 6 Sn 5 界面相对较脆。 CZM的扩展配方可解决负载逆转问题,从而证明了描述渐进式焊料/ IMC界面损坏过程的能力,该过程与相对较脆的界面断裂力学相一致。
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