SF6和Cl等离子体化学中蚀刻的统一特征比例模型

2018 Joint International EUROSOI Workshop and International Conference on Ultimate Integration on Silicon (EUROSOI-ULIS) Pub Date : 2018-03-19 DOI:10.1109/ULIS.2018.8354763

X. Klemenschits, S. Selberherr, L. Filipovic

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引用次数: 1

摘要

提出了一种新的统一特征尺度的感应等离子体刻蚀模型。半经验模型通过只考虑表面反应而忽略反应器中的反应来简化模拟。该模型将蚀刻过程中在侧壁上形成的钝化层视为独立的材料，给出了准确的描述。这使得它们可以明确地包含在随后的蚀刻步骤中，从而更准确地描述物理过程。因此，先进节点的新型栅堆几何形状可以更严格地建模，从而更好地理解在栅堆蚀刻过程中发生的复杂化学和物理过程。将该模型应用于14nm制程CMOS器件的栅极叠层几何结构分析，并与实验结果进行了比较，结果吻合较好。

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Unified feature scale model for etching in SF6 and Cl plasma chemistries

A novel unified feature-scale model for inductive plasma etching is presented. The semi-empirical model simplifies simulations by considering only surface reactions and ignoring those in the reactor. The model gives an accurate description of passivation layers which form on sidewalls during etch processes, by treating them as independent materials. This allows them to be explicitly included in subsequent etch steps, resulting in a more accurate description of the physical process. Therefore, novel gate stack geometries for advanced nodes can be modelled more rigorously, enabling a better understanding of the complex chemical and physical processes taking place during the gate stack etching sequence. The model was applied in the analysis of a gate stack geometry for CMOS devices of a 14nm process and compared to experimental results, which are in good agreement.

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来源期刊

2018 Joint International EUROSOI Workshop and International Conference on Ultimate Integration on Silicon (EUROSOI-ULIS)

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