Liu Shu, Chongyang Li, Yunwen Wu, Tao Hang, Lei Liu, Ming Li
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引用次数: 0
摘要
在以微型化为主要驱动力的半导体行业,超薄芯片的机械性能日益成为重要的研究课题。表面下损伤(SSD)是晶圆减薄过程中的常见问题,但目前还缺乏关于 SSD 微观结构与超薄模具强度之间关系的研究。在本研究中,通过对采用不同晶片减薄方法制备的超薄模具进行三点弯曲测试,并结合 SSD 微观结构表征,研究了 SSD 微观结构对抗弯强度的影响。使用 N 垫干磨的模具抗弯强度最高,使用 M 垫干磨的模具抗弯强度居中,而使用精磨的模具抗弯强度最低。我们用高分辨率透射电子显微镜(HRTEM)研究了 SSD 的微观结构,发现它包括非晶区、微裂纹和高密度变形区。精磨样品的 SSD 较厚且断断续续,可观察到微裂纹。相比之下,M 研磨垫抛光的 SSD 结构均匀但较厚,而 N 研磨垫抛光的 SSD 较薄但变化较大。SSD 厚度不仅影响平均值,还决定了抗弯强度的分布。这项研究加深了人们对固态硬碟微观结构对超薄芯片抗弯强度影响的理解,为优化晶片减薄工艺以提高芯片可靠性提供了宝贵的见解。
The influence of sub-surface damage microstructure on ultra-thin die flexural strength
In the semiconductor industry, where miniaturization is a key driver, mechanical properties of ultra-thin dies are increasingly important research topics. Sub-surface damage (SSD) is a common issue in wafer thinning processes, but there is a lack of research on the relationship between SSD microstructure and ultra-thin die strength. In this study, the influence of SSD microstructure on flexural strength was investigated through three-point bending tests of ultra-thin dies prepared by distinct wafer-thinning methods, coupled with SSD microstructure characterization. Flexural strength was highest for dies dry polished with N pad, intermediate for dies dry polished with M pad, and lowest for dies with fine grinding. We researched SSD microstructure by high-resolution transmitted electron microscope (HRTEM), revealing that it comprises amorphous regions, micro-cracks, and high-density distortion areas. The SSD of the fine grinding samples was thick and intermittent, with observable micro-cracks. Comparatively, the SSD structure from M pad polishing was uniform but thicker, whereas SSD from N pad polishing was thinner but exhibited greater variability. SSD thickness not only influences the average value but also dictates the distribution of flexural strength. This research enhances the understanding of SSD microstructure's impact on ultra-thin die flexural strength, providing valuable insights for optimizing wafer thinning processes to enhance die reliability.