Design and Optimization of 22 nm Gate Length High-k/Metal gate NMOS Transistor

In this paper, we invented the optimization experiment design of a 22 nm gate length NMOS device which uses a combination of high-k material and metal as the gate which was numerically developed using an industrial-based simulator. The high-k material is Titanium dioxide (TiO2), while the metal gate...

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Veröffentlicht in:	Journal of physics. Conference series 2013-01, Vol.431 (1), p.12026-9, Article 1
Hauptverfasser:	Afifah Maheran, A H, Menon, P S, Ahmad, I, Shaari, S, Elgomati, H A, Salehuddin, F
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Sprache:	eng
Schlagworte:	Analysis of variance Design engineering Design of experiments Design optimization Design parameters Gates Mathematical models Metal silicides MOS devices Optimization Physics Process parameters Signal to noise ratio Silicides Taguchi methods Threshold voltage Titanium Titanium dioxide Transistors Tungsten compounds Variance Variance analysis
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creator	Afifah Maheran, A H Menon, P S Ahmad, I Shaari, S Elgomati, H A Salehuddin, F
description	In this paper, we invented the optimization experiment design of a 22 nm gate length NMOS device which uses a combination of high-k material and metal as the gate which was numerically developed using an industrial-based simulator. The high-k material is Titanium dioxide (TiO2), while the metal gate is Tungsten Silicide (WSix). The design is optimized using the L9 Taguchi method to get the optimum parameter design. There are four process parameters and two noise parameters which were varied for analyzing the effect on the threshold voltage (Vth). The objective of this experiment is to minimize the variance of Vth where Taguchi's nominal-the-best signal-to-noise ratio (S/N Ratio) was used. The best settings of the process parameters were determined using Analysis of Mean (ANOM) and analysis of variance (ANOVA) to reduce the variability of Vth. The results show that the Vth values have least variance and the mean value can be adjusted to 0.306V ±0.027 for the NMOS device which is in line with projections by the ITRS specifications.
doi_str_mv	10.1088/1742-6596/431/1/012026
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subjects	Analysis of variance Design engineering Design of experiments Design optimization Design parameters Gates Mathematical models Metal silicides MOS devices Optimization Physics Process parameters Signal to noise ratio Silicides Taguchi methods Threshold voltage Titanium Titanium dioxide Transistors Tungsten compounds Variance Variance analysis
title	Design and Optimization of 22 nm Gate Length High-k/Metal gate NMOS Transistor
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