感应加热晶圆级封装的热力学分析

Wenming Liu, Mingxiang Chen, Yanyan Xi, Changyong Lin, Sheng Liu
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引用次数: 7

摘要

本文采用非线性单向耦合有限元框架来模拟圆片级封装的感应加热过程。基于感应加热的数值结果,对单面陶瓷片的热致翘曲和应力进行了计算。为了验证数值方法的正确性,还进行了一些初步实验。利用三维模型,可以清晰地描述单面陶瓷片在感应加热下的温度分布、热致翘曲和应力。此外,在建模中还考虑了与温度相关的材料特性。从有限元分析中发现,感应加热具有选择性,即在感应加热过程中,晶圆内的温度低于铜环内的温度;铜环上的温度变化以及铜环与晶圆之间的温度差异与晶圆材料的性质有关;诱导焦耳热引起的最大热应力发生在单面陶瓷片的中边缘区域。另一方面,为了证明本文所建立的框架的合理性,将红外辐射计得到的测试结果与所提出的数值分析方法得到的测试结果进行了比较。结果表明,感应加热过程中由热应力引起的温度变化和初始裂纹位置与试验结果吻合较好。
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Thermo-mechanical analysis of a wafer level packaging by induction heating
In this paper, a non-linear and one-directional coupled finite element framework has been implemented to simulate induction heating process of wafer-level packaging. Based on numerical results of induction heating, thermally-caused warpages and stresses of the single-sided ceramic wafer have been evaluated. Some primary experiments have also been conducted to verify the numerical method. Using three-dimensional models, the temperature distribution, thermally-caused warpages and stress in the single-sided ceramic wafer subjected to induction heating can be clearly defined. In addition, the temperature-dependent material properties are considered in the modeling. From the finite element analysis, it is found that the induction heating is selective, that is, the temperature in the wafer is lower than that of Cu-loops during the induction heating process; the temperature variation on the Cu-loops, as well as the difference of the temperature between the Cu-loops and the wafer is related with the wafer material properties; the maximum thermal-stresses caused by the induced Joule heating occur on the middle-edge areas of the single-sided ceramic wafer. On the other hand, in order to prove the soundness of the framework established in this paper, the test results obtained by infrared radiometer are compared to that achieved from the proposed numerical analysis method. It is shown that the temperature variation and locations of initial cracks caused by thermal-stresses during the induction heating are in a good agreement with those obtained from the test.
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