Enhanced performance of 19 single gate MOSFET with high permittivity dielectric material

In this research, the performance of the 19 nm single gate MOSFET is enhanced through the implementation of the high permittivity dielectric material. The MOSFET scaling trends necessities in device dimensions can be satisfied through the implementation of the high-K dielectric materials in place of...

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Main Authors: Roslan A.F., Salehuddin F., Zain A.S.M., Kaharudin K.E., Ahmad I.
Other Authors: 57203514087
Format: Article
Published: Institute of Advanced Engineering and Science 2023
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spelling my.uniten.dspace-257832023-05-29T16:14:13Z Enhanced performance of 19 single gate MOSFET with high permittivity dielectric material Roslan A.F. Salehuddin F. Zain A.S.M. Kaharudin K.E. Ahmad I. 57203514087 36239165300 55925762500 56472706900 12792216600 In this research, the performance of the 19 nm single gate MOSFET is enhanced through the implementation of the high permittivity dielectric material. The MOSFET scaling trends necessities in device dimensions can be satisfied through the implementation of the high-K dielectric materials in place of the SiO2. Therefore, the 19 nm n-channel MOSFET device with different High-K dielectric materials are implemented and its performance improvement has also been analysed. Virtual fabrication is exercised through ATHENA module from Silvaco TCAD tool. Meanwhile, the device characteristic was utilized by using an ATLAS module. The aforementioned materials have also been simulated and compared with the conventional gate oxide SiO2 for the same structure. At the end, the results have proved that Titanium oxide (TiO2) device is the best dielectric material with a combination of metal gate Tungsten Silicides (WSix). The drive current (ION) of this device (WSix/TiO2) is 587.6 ?A/um at 0.534 V of threshold voltage (VTH) as opposed to the targeted 0.530 V predicted, as well as a relatively low IOFF that is obtained at 1.92 pA/?m. This ION value meets the minimum requirement predicted by International Technology Roadmap for Semiconductor (ITRS) 2013 prediction for low performance (LP) technology. Copyright � 2020 Institute of Advanced Engineering and Science. All rights reserved. Final 2023-05-29T08:14:13Z 2023-05-29T08:14:13Z 2020 Article 10.11591/ijeecs.v18.i2.pp724-730 2-s2.0-85078212031 https://www.scopus.com/inward/record.uri?eid=2-s2.0-85078212031&doi=10.11591%2fijeecs.v18.i2.pp724-730&partnerID=40&md5=7820e38f30c4e7c484939bce4b49ee51 https://irepository.uniten.edu.my/handle/123456789/25783 18 2 724 730 All Open Access, Gold, Green Institute of Advanced Engineering and Science Scopus
institution Universiti Tenaga Nasional
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description In this research, the performance of the 19 nm single gate MOSFET is enhanced through the implementation of the high permittivity dielectric material. The MOSFET scaling trends necessities in device dimensions can be satisfied through the implementation of the high-K dielectric materials in place of the SiO2. Therefore, the 19 nm n-channel MOSFET device with different High-K dielectric materials are implemented and its performance improvement has also been analysed. Virtual fabrication is exercised through ATHENA module from Silvaco TCAD tool. Meanwhile, the device characteristic was utilized by using an ATLAS module. The aforementioned materials have also been simulated and compared with the conventional gate oxide SiO2 for the same structure. At the end, the results have proved that Titanium oxide (TiO2) device is the best dielectric material with a combination of metal gate Tungsten Silicides (WSix). The drive current (ION) of this device (WSix/TiO2) is 587.6 ?A/um at 0.534 V of threshold voltage (VTH) as opposed to the targeted 0.530 V predicted, as well as a relatively low IOFF that is obtained at 1.92 pA/?m. This ION value meets the minimum requirement predicted by International Technology Roadmap for Semiconductor (ITRS) 2013 prediction for low performance (LP) technology. Copyright � 2020 Institute of Advanced Engineering and Science. All rights reserved.
author2 57203514087
author_facet 57203514087
Roslan A.F.
Salehuddin F.
Zain A.S.M.
Kaharudin K.E.
Ahmad I.
format Article
author Roslan A.F.
Salehuddin F.
Zain A.S.M.
Kaharudin K.E.
Ahmad I.
spellingShingle Roslan A.F.
Salehuddin F.
Zain A.S.M.
Kaharudin K.E.
Ahmad I.
Enhanced performance of 19 single gate MOSFET with high permittivity dielectric material
author_sort Roslan A.F.
title Enhanced performance of 19 single gate MOSFET with high permittivity dielectric material
title_short Enhanced performance of 19 single gate MOSFET with high permittivity dielectric material
title_full Enhanced performance of 19 single gate MOSFET with high permittivity dielectric material
title_fullStr Enhanced performance of 19 single gate MOSFET with high permittivity dielectric material
title_full_unstemmed Enhanced performance of 19 single gate MOSFET with high permittivity dielectric material
title_sort enhanced performance of 19 single gate mosfet with high permittivity dielectric material
publisher Institute of Advanced Engineering and Science
publishDate 2023
_version_ 1806427470041186304
score 13.212058