At the present time, life acceleration factors for solder joints made of SnAgCu (SAC) ternary alloys between accelerated tests and field use conditions are not well understood. Further, the cycle time for accelerated testing of Pb-free solders is currently an industry concern since the rate of damage accumulation due to therrnomechanical loading in Pb-free solders is different from the eutectic Sn-Pb solders. In this study, we develop an understanding of the acceleration factors through a combination of temperature cycling tests, powercycling tests and validated damage modeling. We begin by describing a recently developed Simulated Power Cycling (SPC) tester that is a simplified powercycling test procedure. The tester uses an external thermoelectric device to heat the package surface. Through localized heating, the thermoelectric device enables rapid cycling of packages unlike in thermal chambers. We report temperature and powercycling reliability data on Pb-free, Sn4Ag0.5Cu 36 I/O Wafer Level-Chip Scale Packages (WL-CSP). We compare the results of powercycling against -40° to 125° C temperature cycling test results. In both, fatigue failure by near interfacial crack growth was discovered to progress from the outside edge of the joints towards the center of the package. Creep and shear dominated microscopic failure modes were found on the solder joint fracture surfaces. Further, we observe in both cases that there are no diagonal cracks, secondary cracks are scarce and the effect of voids on crack growth is insignificant compared to the location of the joint on the package, which determines the stress on the joint. The fracture morphology due to. fatigue crack growth was nearly identical close to and far from the crack initiation site, revealing similar damage mechanisms during all stages of life. Finally, we propose a procedure for extracting acceleration factors based on a recently developed (and experimentally validated for Sn-Pb solder joints) damage accumulation theory inspired by the cohesive zone models of modern fracture mechanics, The proposed model is non-empirical unlike the Coffin-Manson rule and simulates the actual progression of crack through the joint.
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机译:目前,对加速试验和现场使用条件之间的SnAGCU(SAC)三元合金制成的焊点的焊点寿命加速因子尚不清楚。此外,对无铅焊料的加速测试的循环时间目前是行业问题,因为由于PB免焊料中由于Thernom机械负载导致的损伤率不同于共晶Sn-Pb焊料。在这项研究中,我们通过温度循环试验,动力测试和验证损坏建模的组合来了解对加速因素的理解。我们首先描述了最近开发的模拟功率循环(SPC)测试仪,该测试仪是简化的动力转换测试程序。测试仪使用外部热电装置加热包装表面。通过局部加热,热电装置能够快速循环包装,与热腔室不同。我们在无铅,SN4AG0.5CU 36 I / O晶片级芯片尺度套件(WL-CSP)上报告温度和发动力可靠性数据。我们将动力转移的结果与-40°相机进行比较,温度循环测试结果。在这两种情况下,发现靠近界面裂缝的疲劳失效被发现从接头的外边缘朝向包装的中心进行。在焊点骨折表面上发现蠕变和剪切占状衰竭衰竭模式。此外,我们在没有对角裂缝的两种情况下观察到,与包装上的接头的位置相比,二次裂缝是稀缺的,并且空隙对裂缝生长的影响是微不足道的,这与包装上的接头的位置相比,这决定了关节上的应力。由于骨折形态。疲劳裂纹的生长几乎与裂纹引发位点接近,远离裂缝引发位点,在所有生命的所有阶段都揭示了类似的损伤机制。最后,我们提出了一种基于最近开发的(并针对SN-PB焊点的实验验证)提取加速因子的程序,该损伤积累理论受到现代骨折力学的凝聚区模型的启发,所提出的模型与棺材不同-Manson规则并通过联合模拟裂缝的实际进展。
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