Investigation of Quantification of Agglomeration Level of Silica Particles in CMP Slurry for Creating the Quality Prediction Formula by AI Technology

2019 IEEE Albany Nanotechnology Symposium (ANS) Pub Date : 2019-11-01 DOI:10.1109/ANS47466.2019.8963738

Mami Kubota, K. Takanashi, K. Dunn

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Abstract

Artificial Intelligence techniques (AI) offer the possibility of stabilize process control independent of human skills for many industries, including Chemical Mechanical Planarization (CMP) in a silicon wafer manufacturing flow. In this arena, AI is mainly used to develop a formula for predicting the quality of wafers after CMP. In the current stage of AI development, explanatory variables are required to be quantifiable values, and still need to be chosen by a human. Generally, the explanatory variables used are the processing data which is easy to get from CMP equipment in a manufacturing process. However, these values are not directly measuring the conditions of the wafer or the consumables. In this study, we focus on providing more directly relevant data which could serve as inputs for AI algorithms based on the condition of the silica particles in the CMP slurry. In particular, we quantify the agglomeration levels of silica particles (AGL), and investigate the behaviours of AGL at several pressure levels. Further, we explain the relationships between AGL and polishing abilities, as a more relevant input for AI prediction of wafer quality.

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基于人工智能技术的CMP料浆中二氧化硅颗粒团聚水平定量研究及质量预测公式的建立

人工智能技术(AI)为许多行业提供了独立于人类技能的稳定过程控制的可能性，包括硅片制造流程中的化学机械平面化(CMP)。在这个领域，人工智能主要用于开发预测CMP后晶圆质量的公式。在人工智能发展的现阶段，解释变量需要是可量化的值，仍然需要人类来选择。一般来说，使用的解释变量是在制造过程中易于从CMP设备获得的加工数据。然而，这些值并不能直接测量晶圆片或耗材的状况。在这项研究中，我们的重点是提供更直接相关的数据，这些数据可以作为基于CMP浆体中二氧化硅颗粒状况的人工智能算法的输入。特别是，我们量化了二氧化硅颗粒(AGL)的团聚水平，并研究了AGL在不同压力水平下的行为。此外，我们解释了AGL和抛光能力之间的关系，作为人工智能预测晶圆质量的更相关输入。

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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2019 IEEE Albany Nanotechnology Symposium (ANS)

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