Middle-of-line plasma dry etch challenges for CFET integration

D. Radisic, M. Hosseini, H. Mertens, D. Zhou, V. Vega Gonzalez, S. Wang, B. Chan, D. Batuk, E. Dupuy, Z. Tao, E. Dentoni Litta, N. Horiguchi
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Abstract

In this paper, middle-of-line (MOL) plasma etch development results for the monolithic CFET integration with nanosheet devices using scaling-relevant test vehicle (CPP48nm) are presented. Several critical MOL patterning steps are addressed, with the focus on the patterning of the trenches (M0) for contacting to the bottom and top devices. The patterning of M0A consists of SiO2 dielectric and thin SiN liner etch landing on epitaxial source drain (S/D). The critical M0 etch requirement is preserving the SiN gate spacer to avoid shorting between S/D and gate. Due to no-gate plug implementation in the process flow, the etch development must rely on very challenging, patterning the small critical dimension (CD) contacts to create enough dielectric barrier between the metal contact and the gate, and preferably, also very challenging, self-alignment to the thin gate spacer. The dependance of the M0 CD and the etch depth is accessed by using the range of the EUV lithography conditions and evaluating the maximum etch depth of the trench as a function of the printed CD. The minimum trench CD achieved on the bottom of the trench is ~ 13nm, and the minimum top CD in the range of ~ 16nm, with the evident etch non-uniformity observed in the etch depth. The trend of larger contact CD resulting in the deeper etch and process uniformity improvement is observed. Etch depth larger than 100nm is achieved when top M0 CD is >20nm. The option with the SiN liner deposition followed by SiN liner etch (spacer formation) post- M0 SiO2 is developed. This patterning sequence consists of SiO2 etch stopping on the thin SiN (over S/D) followed by additional SiN deposition and finally etching of the deposited SiN liner as well as SiN liner covering S/D. The option with SiN spacer formation minimizes the risk of short to the gate, due to extra SiN dielectric film protecting the gate. In addition, we present the results for another critical MOL patterning step, i.e., HAR metal recess post M0 metallization (AR~11)
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中线等离子体干蚀刻对CFET集成的挑战
本文介绍了采用与缩放相关的测试载体(CPP48nm)进行单片cefet与纳米片器件集成的中线等离子体刻蚀的开发结果。解决了几个关键的MOL图像化步骤,重点是与底部和顶部器件接触的沟槽(M0)的图像化。在外延源漏极(S/D)上,M0A的图形由SiO2介电层和薄薄的SiN衬里蚀刻层组成。关键的M0蚀刻要求是保留SiN栅极间隔,以避免S/D和栅极之间的短路。由于在工艺流程中实现了无栅塞,因此蚀刻开发必须依赖于非常具有挑战性的小临界尺寸(CD)触点图案,以在金属触点和栅极之间创建足够的介电屏障,并且最好也是非常具有挑战性的是,自对准薄栅极垫片。利用EUV光刻条件的范围,对刻蚀深度的最大刻蚀深度作为刻蚀深度的函数进行了评估,得到了M0刻蚀深度与刻蚀深度的依赖关系。在刻蚀深度范围内,刻蚀深度在~ 13nm和~ 16nm范围内达到了最小刻蚀深度。观察到接触面CD增大的趋势导致更深的蚀刻和工艺均匀性的改善。当最上层M0 CD为bb0 ~ 20nm时,可实现大于100nm的刻蚀深度。开发了在M0 SiO2后进行SiN衬垫沉积,然后进行SiN衬垫蚀刻(间隔层形成)的选择。这个图案序列包括SiO2蚀刻停止在薄SiN上(超过S/D),然后是额外的SiN沉积,最后蚀刻沉积的SiN衬里以及覆盖S/D的SiN衬里。由于额外的SiN介电膜保护栅极,带有SiN间隔层形成的选项最大限度地降低了栅极短路的风险。此外,我们还介绍了另一个关键的MOL图图化步骤,即M0金属化后HAR金属凹槽(AR~11)的结果。
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