RMG技术的过程控制和集成选项，用于大规模设备

2012 Symposium on VLSI Technology (VLSIT) Pub Date : 2012-06-12 DOI:10.1109/VLSIT.2012.6242447

A. Veloso, Y. Higuchi, S. Chew, K. Devriendt, L. Ragnarsson, F. Sebaai, T. Schram, S. Brus, E. Vecchio, K. Kellens, E. Rohr, G. Eneman, E. Simoen, M. Cho, V. Paraschiv, Y. Crabbe, X. Shi, H. Tielens, A. Van Ammel, H. Dekkers, P. Favia, J. Geypen, H. Bender, A. Phatak, J. I. del Agua Borniquel, K. Xu, M. Allen, C. Liu, T. Xu, W. Yoo, A. Thean, N. Horiguchi

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引用次数: 17

摘要

本文报道了通过控制ewf金属合金化NMOS实现的RMG-HKL器件，其Lgate~35nm处具有紧密的低vt分布[σ(VTsat) ~ 29mV (PMOS)， ~ 49mV (NMOS)]，并对其实现特性进行了深入的概述:1)物理机制，TCAD仿真和分析技术(如TEM, EDS)支持的模型;2)工艺优化实施:减少氧源，控制RF-PVD TiAl/TiN比和降低Hgate，同时影响通道中诱导的应力。其他关键特性:1)Al与W作为填充金属，经过仔细的衬垫/阻挡材料选择和调谐，可以产生性能良好的器件，具有紧密的Rgate分布，低至Lgate~20nm，并且可以实现PMOS和NMOS的低vt值用于高纵横比栅极(Hgate~60nm, Lgate≥30nm);2)湿蚀与siconi清洁去除假介电介质，沉积后的HfO2 n2退火导致BTI大幅改善，没有EOT或低场/峰值迁移率损失，并且具有良好的噪声响应。

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Process control & integration options of RMG technology for aggressively scaled devices

We report on aggressively scaled RMG-HKL devices, with tight low-V_T distributions [σ(V_Tsat) ~ 29mV (PMOS), ~ 49mV (NMOS) at L_gate~35nm] achieved through controlled EWF-metal alloying for NMOS, and providing an in-depth overview of its enabling features: 1) physical mechanisms, model supported by TCAD simulations and analysis techniques such as TEM, EDS; 2) process optimizations implementation: oxygen sources reduction, control of RF-PVD TiAl/TiN ratio and reduced H_gate, also impacting stress induced in the channel. Additional key features: 1) Al vs. W as fill-metal, with careful liner/barrier materials selection and tuning yielding well-behaved devices with tight R_gate distributions down to L_gate~20nm, and enabling both PMOS and NMOS low-VT values for high aspect-ratio gates (H_gate~60nm, L_gate≥30nm); 2) wet-etch vs. siconi clean for dummy-dielectric removal, with HfO₂ post-deposition N₂-anneal resulting in substantial BTI improvement without EOT or low-field/peak mobility penalty, and good noise response.

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2012 Symposium on VLSI Technology (VLSIT)

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