Analyze and optimize the silicide thickness in 45nm CMOS technology using Taguchi method

Taguchi method was used to analyze the experimental data in order to get the optimum average of silicide thickness in 45nm devices. The virtually fabrication of the devices was performed by using ATHENA module. While the electrical characterization of the devices was implemented by using ATLAS modul...

Full description

Saved in:
Bibliographic Details
Main Authors: Salehuddin, F., Ahmad, I., Hamid, F.A., Zaharim, A.
Format: Conference Proceeding
Published: 2017
Online Access:http://dspace.uniten.edu.my:80/jspui/handle/123456789/5249
Tags: Add Tag
No Tags, Be the first to tag this record!
id my.uniten.dspace-5249
record_format dspace
spelling my.uniten.dspace-52492018-03-02T03:32:21Z Analyze and optimize the silicide thickness in 45nm CMOS technology using Taguchi method Salehuddin, F. Ahmad, I. Hamid, F.A. Zaharim, A. Taguchi method was used to analyze the experimental data in order to get the optimum average of silicide thickness in 45nm devices. The virtually fabrication of the devices was performed by using ATHENA module. While the electrical characterization of the devices was implemented by using ATLAS module. These two modules were used as design tools and helps to reduce design time and cost. In this paper, both modules and Taguchi method was combined to aid in design and optimizer the process parameters. There are four process parameters (factors), namely Halo Implantation, Source/Drain (S/D) Implantation, Oxide Growth Temperature and Silicide Anneal temperature. These factors were varied for 3 levels to perform 9 experiments. Threshold voltage (VTH) results were used as the evaluation variables. Then, the results were subjected to the Taguchi method for determine the optimal process parameters and to produce predicted values. The predicted values of the process parameters were successfully verified with ATHENA and ATLAS's simulator. The results show that the average of silicide thickness after optimizations approaches was 30.66nm and 30.58nm for NMOS and PMOS devices respectively. In this research, Halo Implantation was identified as one of the process parameters that has the strongest effect on the response characteristics. While the S/D Implantation was identified as an adjustment factor to get the nominal values of threshold voltage for PMOS and NMOS devices equal to -0.1501V and +0.150047V respectively. © 2010 IEEE. 2017-11-15T02:57:02Z 2017-11-15T02:57:02Z 2010 Conference Proceeding http://dspace.uniten.edu.my:80/jspui/handle/123456789/5249 10.1109/SMELEC.2010.5549488
institution Universiti Tenaga Nasional
building UNITEN Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Tenaga Nasional
content_source UNITEN Institutional Repository
url_provider http://dspace.uniten.edu.my/
description Taguchi method was used to analyze the experimental data in order to get the optimum average of silicide thickness in 45nm devices. The virtually fabrication of the devices was performed by using ATHENA module. While the electrical characterization of the devices was implemented by using ATLAS module. These two modules were used as design tools and helps to reduce design time and cost. In this paper, both modules and Taguchi method was combined to aid in design and optimizer the process parameters. There are four process parameters (factors), namely Halo Implantation, Source/Drain (S/D) Implantation, Oxide Growth Temperature and Silicide Anneal temperature. These factors were varied for 3 levels to perform 9 experiments. Threshold voltage (VTH) results were used as the evaluation variables. Then, the results were subjected to the Taguchi method for determine the optimal process parameters and to produce predicted values. The predicted values of the process parameters were successfully verified with ATHENA and ATLAS's simulator. The results show that the average of silicide thickness after optimizations approaches was 30.66nm and 30.58nm for NMOS and PMOS devices respectively. In this research, Halo Implantation was identified as one of the process parameters that has the strongest effect on the response characteristics. While the S/D Implantation was identified as an adjustment factor to get the nominal values of threshold voltage for PMOS and NMOS devices equal to -0.1501V and +0.150047V respectively. © 2010 IEEE.
format Conference Proceeding
author Salehuddin, F.
Ahmad, I.
Hamid, F.A.
Zaharim, A.
spellingShingle Salehuddin, F.
Ahmad, I.
Hamid, F.A.
Zaharim, A.
Analyze and optimize the silicide thickness in 45nm CMOS technology using Taguchi method
author_facet Salehuddin, F.
Ahmad, I.
Hamid, F.A.
Zaharim, A.
author_sort Salehuddin, F.
title Analyze and optimize the silicide thickness in 45nm CMOS technology using Taguchi method
title_short Analyze and optimize the silicide thickness in 45nm CMOS technology using Taguchi method
title_full Analyze and optimize the silicide thickness in 45nm CMOS technology using Taguchi method
title_fullStr Analyze and optimize the silicide thickness in 45nm CMOS technology using Taguchi method
title_full_unstemmed Analyze and optimize the silicide thickness in 45nm CMOS technology using Taguchi method
title_sort analyze and optimize the silicide thickness in 45nm cmos technology using taguchi method
publishDate 2017
url http://dspace.uniten.edu.my:80/jspui/handle/123456789/5249
_version_ 1644493627837120512
score 13.222552