Challenges for spacer and source/drain cavity patterning in CFET devices

G. Mannaert, H. Mertens, M. Hosseini, S. Demuynck, V. Nguyen, B. Chan, F. Lazzarino
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引用次数: 1

Abstract

In a complementary-FET (CFET), n- and p- type transistors are stacked on top of each other. This stacking approach results in very high aspect ratio vertical features which brings critical challenges for nanosheet (NSH), gate, spacer, and source/drain (S/D) cavity patterning. Silicon nitride spacers are commonly used to electrically isolate and protect the silicon gate during S/D epitaxial growth and to precisely define the channel length (Lg) [1-4]. In this work, we will discuss the spacer film opening, the optimization of the S/D cavity profile and propose options to reduce the gate hard mask consumption. We were able to straighten the S/D cavity profile in the SiGe superlattice substrate by tuning specific process parameters, during the various etch and over-etch steps of the stack. Chemical analysis of the sidewall of the cavity, by TEM/EDS, confirmed that the formation of a passivation oxi-nitride compound is key to achieve vertical cavity profile. The chemical mapping of the cavity was done through the Si and SiGe25% sheets. A Si, O and N containing passivation layer is present in the cavity which seems to be thicker at the top and thinner at the bottom of the cavity. Furthermore, polymer capping methods were investigated to reduce the consumption of oxide hard mask (HM) during spacer etch. Process optimization for the cavity shape in the S/D recess etch was conducted using TEM characterization.
CFET器件中间隔器和源/漏腔设计的挑战
在互补型场效应管中,n型和p型晶体管彼此堆叠在一起。这种叠加方法导致了非常高的纵横比垂直特征,这给纳米片(NSH)、栅极、间隔层和源/漏极(S/D)腔模式带来了关键挑战。氮化硅间隔层通常用于在S/D外延生长过程中对硅栅进行电隔离和保护,并精确定义通道长度(Lg)[1-4]。在这项工作中,我们将讨论间隔膜开度,S/D型腔轮廓的优化,并提出减少栅极硬掩模消耗的方案。我们能够通过调整特定的工艺参数,在堆栈的各种蚀刻和过蚀刻步骤中,拉直SiGe超晶格衬底中的S/D腔廓。通过TEM/EDS对空腔侧壁的化学分析,证实了钝化氧化氮化合物的形成是实现垂直空腔轮廓的关键。通过Si和SiGe25%薄片完成空腔的化学映射。含Si、O和N的钝化层存在于空腔中,其顶部较厚,底部较薄。此外,还研究了聚合物封顶方法,以减少间隔片蚀刻过程中氧化物硬掩膜(HM)的消耗。利用透射电镜对S/D凹槽蚀刻工艺进行了优化。
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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