纳米线和GAA晶体管选择性各向同性硅刻蚀的特点

C. Catano, Nicholas A. Joy, Christopher Talone, Shyam Sridhar, S. Voronin, P. Biolsi, A. Ranjan
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引用次数: 2

摘要

在集成电路制造的世界里,为了提高速度、性能和成本,不断努力增加器件密度。目前的技术正在推动器件从使用平面晶体管过渡到更“3D”的设计,如纳米线甚至垂直定向晶体管。纳米线器件的制造是3D蚀刻挑战的一个很好的例子,其中需要各向异性和高选择性各向同性蚀刻工艺。交替的Si和SiGe层首先垂直蚀刻,然后彼此选择性地嵌入。有一些文献报道已经证明了SiGe选择性地嵌入Si的能力,然而相反的情况并没有得到很好的证实。这项任务的关键挑战是最大限度地提高对SiGe层以及晶圆上暴露的任何其他间隔和掩膜材料(包括SiO2, Si3N4, SiOCN和SiBCN)的选择性。在这项工作中,我们研究了在CF4/O2/N2和NF3/O2/N2基等离子体中选择性Si到SiGe的各向同性刻蚀,其选择性高于50:1。潜在的选择性机制是基于混合SiGe层优先氧化而不是Si,而NO分子的形成会导致Si表面过多的氧化层被去除。1,2提出了一个定性模型来描述用这种化学方法得到的蚀刻轮廓。关于F:O比、温度和硅层厚度依赖关系的支持数据显示在支持模型的努力中。这些结果将为行业决定哪种工艺解决方案最适合GAA器件提供重要的见解。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Peculiarities of selective isotropic Si etch to SiGe for nanowire and GAA transistors
Within the world of integrated circuit manufacturing there is a continuous effort to increase device density in order to improve speed, performance and costs. Current technology is driving a transition from devices that use a planar transistor to a more “3D” design, such as with nanowires or even vertically oriented transistors. The fabrication of nanowire devices demonstrates a good example of 3D etch challenges where both anisotropic and highly selective isotropic etch processes are needed. Alternating Si and SiGe layers are first etched vertically, then are later recessed selective to one another. There are a number of literature reports which have demonstrated the capability of recessing SiGe selective to Si, however the opposite is not as well established. The key challenges of this task are maximizing the selectivity to the SiGe layers as well as any other spacer and mask materials exposed on the wafer including SiO2, Si3N4, SiOCN and SiBCN. In this work, we present a study of isotropic etching for Si selective to SiGe in CF4/O2/N2 and NF3/O2/N2 based plasmas with selectivities higher than 50:1 achieved. Potential selectivity mechanisms are based on preferential oxidation of mixed SiGe layers opposed to Si, while formation of the NO molecule can result in excessive oxide layer removal from the Si surface.1,2 A qualitative model is put forth to describe the resulting etch profiles using this chemistry. Supporting data regarding F:O ratio, temperature, and Si layer thickness dependency are shown in efforts to support the model. These results will provide essential insight as the industry decides which process solution is optimal for GAA devices.
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