Modeling of 14 nm gate length n-Type MOSFET

Metal-Oxide-Semiconductor Field Effect Transistors MOSFETs (MOSFETs) transistor have been scaled tremendously through Moore's Law since 1974 in order to compact transistors in a single chip. Thus, a proper scaling technique is compulsory to minimize the short channel effect (SCE) problems. In t...

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Main Authors: Faizah, Z.A.N., Ahmad, I., Ker, P.J., Roslan, P.S.A., Maheran, A.H.A.
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Published: 2017
Online Access:http://dspace.uniten.edu.my/jspui/handle/123456789/5980
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spelling my.uniten.dspace-59802020-09-10T04:11:35Z Modeling of 14 nm gate length n-Type MOSFET Faizah, Z.A.N. Ahmad, I. Ker, P.J. Roslan, P.S.A. Maheran, A.H.A. Metal-Oxide-Semiconductor Field Effect Transistors MOSFETs (MOSFETs) transistor have been scaled tremendously through Moore's Law since 1974 in order to compact transistors in a single chip. Thus, a proper scaling technique is compulsory to minimize the short channel effect (SCE) problems. In this paper, the virtual fabricated design and device's characterization of 14 nm HfO2/WSi2 n-type MOSFET device is presented. The device is scaled based on previous research on 32 nm transistors. The virtual fabrication and simulation of n-type MOSFETs are implemented using Virtual Wafer Fabrication (VWF) Silvaco TCAD Tools named ATHENA and ATLAS. From the simulation, result shows that the optimal value of threshold voltage (VTH), drive current (ION) and leakage current (IOFF) are 0.232291 V, 78.922×10-6 A/um and 77.11×10-9 A/um respectively. These simulation results are believed to be able to create a touchstone towards the optimization and fabrication of 14 nm device's gate length utilizing High-K/Metal Gate n-type MOSFET in impending work. © 2015 IEEE. 2017-12-08T07:48:13Z 2017-12-08T07:48:13Z 2015 http://dspace.uniten.edu.my/jspui/handle/123456789/5980
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description Metal-Oxide-Semiconductor Field Effect Transistors MOSFETs (MOSFETs) transistor have been scaled tremendously through Moore's Law since 1974 in order to compact transistors in a single chip. Thus, a proper scaling technique is compulsory to minimize the short channel effect (SCE) problems. In this paper, the virtual fabricated design and device's characterization of 14 nm HfO2/WSi2 n-type MOSFET device is presented. The device is scaled based on previous research on 32 nm transistors. The virtual fabrication and simulation of n-type MOSFETs are implemented using Virtual Wafer Fabrication (VWF) Silvaco TCAD Tools named ATHENA and ATLAS. From the simulation, result shows that the optimal value of threshold voltage (VTH), drive current (ION) and leakage current (IOFF) are 0.232291 V, 78.922×10-6 A/um and 77.11×10-9 A/um respectively. These simulation results are believed to be able to create a touchstone towards the optimization and fabrication of 14 nm device's gate length utilizing High-K/Metal Gate n-type MOSFET in impending work. © 2015 IEEE.
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author Faizah, Z.A.N.
Ahmad, I.
Ker, P.J.
Roslan, P.S.A.
Maheran, A.H.A.
spellingShingle Faizah, Z.A.N.
Ahmad, I.
Ker, P.J.
Roslan, P.S.A.
Maheran, A.H.A.
Modeling of 14 nm gate length n-Type MOSFET
author_facet Faizah, Z.A.N.
Ahmad, I.
Ker, P.J.
Roslan, P.S.A.
Maheran, A.H.A.
author_sort Faizah, Z.A.N.
title Modeling of 14 nm gate length n-Type MOSFET
title_short Modeling of 14 nm gate length n-Type MOSFET
title_full Modeling of 14 nm gate length n-Type MOSFET
title_fullStr Modeling of 14 nm gate length n-Type MOSFET
title_full_unstemmed Modeling of 14 nm gate length n-Type MOSFET
title_sort modeling of 14 nm gate length n-type mosfet
publishDate 2017
url http://dspace.uniten.edu.my/jspui/handle/123456789/5980
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score 13.222552