Impact of different dose and angle in HALO structure for 45nm NMOS device
In this paper, we investigates the different dose and tilt HALO implant step in order to characterize the 45nm NMOS device. Besides HALO, the other two process parameters are oxide growth temperature and source/drain (S/D) implant dose. The settings of process parameters were determined by using Tag...
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my.uniten.dspace-295012023-12-28T14:30:16Z Impact of different dose and angle in HALO structure for 45nm NMOS device Salehuddin F. Ahmad I. Hamid F.A. Zaharim A. 36239165300 12792216600 6603573875 15119466900 45nm NMOS Component HALO structure S/D implant Taguchi method TCAD Growth temperature Simulators Taguchi methods Technology Threshold voltage 45nm NMOS Component HALO structure Taguchi TCAD Manufacture In this paper, we investigates the different dose and tilt HALO implant step in order to characterize the 45nm NMOS device. Besides HALO, the other two process parameters are oxide growth temperature and source/drain (S/D) implant dose. The settings of process parameters were determined by using Taguchi experimental design method. This work was done using TCAD simulator, consisting of a process simulator, ATHENA and device simulator, ATLAS. These two simulators were combined with Taguchi method to aid in design and optimizer the process parameters. Threshold voltage (V TH) results were used as the evaluation variable. The results were then subjected to the Taguchi method to determine the optimal process parameters and to produce predicted values. In this research, oxide growth temperature was the major factor affecting the threshold voltage (69%), whereas halo implant tilt was the second ranking factor (20%). The percent effect on Signal-to-Noice (S/N) ratio of halo implant dose and S/D implant dose are 6% and 5% respectively. As conclusions, oxide growth temperature and halo implant tilt were identified as the process parameters that have strongest effect on the response characteristics. While S/D implant dose was identified as an adjustment factor to get threshold voltage for NMOS device closer to the nominal value (0.150V) at t ox= 1.1nm. Final 2023-12-28T06:30:16Z 2023-12-28T06:30:16Z 2012 Conference paper 10.4028/www.scientific.net/AMR.383-390.6827 2-s2.0-83755188202 https://www.scopus.com/inward/record.uri?eid=2-s2.0-83755188202&doi=10.4028%2fwww.scientific.net%2fAMR.383-390.6827&partnerID=40&md5=bb89f1732e2ac0733eae908a97726f34 https://irepository.uniten.edu.my/handle/123456789/29501 383-390 6827 6833 Scopus |
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45nm NMOS Component HALO structure S/D implant Taguchi method TCAD Growth temperature Simulators Taguchi methods Technology Threshold voltage 45nm NMOS Component HALO structure Taguchi TCAD Manufacture |
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45nm NMOS Component HALO structure S/D implant Taguchi method TCAD Growth temperature Simulators Taguchi methods Technology Threshold voltage 45nm NMOS Component HALO structure Taguchi TCAD Manufacture Salehuddin F. Ahmad I. Hamid F.A. Zaharim A. Impact of different dose and angle in HALO structure for 45nm NMOS device |
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In this paper, we investigates the different dose and tilt HALO implant step in order to characterize the 45nm NMOS device. Besides HALO, the other two process parameters are oxide growth temperature and source/drain (S/D) implant dose. The settings of process parameters were determined by using Taguchi experimental design method. This work was done using TCAD simulator, consisting of a process simulator, ATHENA and device simulator, ATLAS. These two simulators were combined with Taguchi method to aid in design and optimizer the process parameters. Threshold voltage (V TH) results were used as the evaluation variable. The results were then subjected to the Taguchi method to determine the optimal process parameters and to produce predicted values. In this research, oxide growth temperature was the major factor affecting the threshold voltage (69%), whereas halo implant tilt was the second ranking factor (20%). The percent effect on Signal-to-Noice (S/N) ratio of halo implant dose and S/D implant dose are 6% and 5% respectively. As conclusions, oxide growth temperature and halo implant tilt were identified as the process parameters that have strongest effect on the response characteristics. While S/D implant dose was identified as an adjustment factor to get threshold voltage for NMOS device closer to the nominal value (0.150V) at t ox= 1.1nm. |
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36239165300 |
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36239165300 Salehuddin F. Ahmad I. Hamid F.A. Zaharim A. |
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Conference paper |
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Salehuddin F. Ahmad I. Hamid F.A. Zaharim A. |
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Salehuddin F. |
title |
Impact of different dose and angle in HALO structure for 45nm NMOS device |
title_short |
Impact of different dose and angle in HALO structure for 45nm NMOS device |
title_full |
Impact of different dose and angle in HALO structure for 45nm NMOS device |
title_fullStr |
Impact of different dose and angle in HALO structure for 45nm NMOS device |
title_full_unstemmed |
Impact of different dose and angle in HALO structure for 45nm NMOS device |
title_sort |
impact of different dose and angle in halo structure for 45nm nmos device |
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2023 |
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1806427528052604928 |
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13.222552 |