Process challenges in low-k wafer dicing

IEEE/CPMT/SEMI 28th International Electronics Manufacturing Technology Symposium, 2003. IEMT 2003. Pub Date : 2003-07-16 DOI:10.1109/IEMT.2003.1225935

Hanxie Zhao, D. Shi

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引用次数: 14

Abstract

Rapid developments in semiconductor industry and the need to maintain interconnect performance as feature sizes shrink are driving a transition to low dielectric constant (k) materials. The very different chemistries and materials properties of low-k dielectric materials may impose novel challenges to wafer/chip manufacturing and packaging processes. Process integration thus becomes more difficult due to the profound changes in properties compared with traditional dielectric materials. Dicing (or sawing) is the first step in the packaging process and its quality can have a significant impact on yields, as well as on device reliability. This paper describes dicing of eight types of Spin-On and CVD low-k wafers. Effects of various blades and dicing process parameters, as well as their combined effect on quality and yield, are discussed. In addition, the effect of cut depth is also examined. Various problems encountered in low-k wafer dicing are presented, and considerations and potential solutions for overcoming these quality obstacles in low-k wafer dicing are discussed. The study shows that the optimized dicing processes must be based on the actual low-k materials, wafer structures and process history of the low-k wafers.

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低钾晶圆切割的工艺挑战

半导体工业的快速发展以及在特征尺寸缩小的同时保持互连性能的需求正在推动向低介电常数(k)材料的过渡。低k介电材料的不同化学性质和材料特性可能给晶圆/芯片制造和封装工艺带来新的挑战。与传统的介电材料相比，由于性能的深刻变化，工艺集成变得更加困难。切丁(或锯)是封装过程中的第一步，其质量对产量和设备可靠性有重大影响。本文介绍了八种自旋和CVD低钾硅片的切割。讨论了各种刀片和切丁工艺参数对质量和产量的影响，以及它们的综合影响。此外，还考察了切割深度的影响。介绍了低钾晶圆切割过程中遇到的各种问题，并讨论了克服这些质量障碍的考虑和可能的解决方案。研究表明，优化的切割工艺必须基于实际的低钾材料、晶圆结构和低钾晶圆的工艺历史。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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IEEE/CPMT/SEMI 28th International Electronics Manufacturing Technology Symposium, 2003. IEMT 2003.

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