A feasible alternative to fdsoi and finfet: Optimization of w/la2o3/si planar pmos with 14 nm gate-length

Cost effectiveness; Fins (heat exchange); Gate dielectrics; Graphene; High-k dielectric; Low-k dielectric; Silica; Silicon on insulator technology; Silicon oxides; Silicon wafers; Threshold voltage; Voltage scaling; Feasible alternatives; Fin field-effect transistors; Fully depleted silicon-on-insul...

Full description

Saved in:
Bibliographic Details
Main Authors: Mah S.K., Ker P.J., Ahmad I., Zainul Abidin N.F., Ali Gamel M.M.
Other Authors: 57191706660
Format: Article
Published: MDPI 2023
Tags: Add Tag
No Tags, Be the first to tag this record!
id my.uniten.dspace-25971
record_format dspace
spelling my.uniten.dspace-259712023-05-29T17:05:50Z A feasible alternative to fdsoi and finfet: Optimization of w/la2o3/si planar pmos with 14 nm gate-length Mah S.K. Ker P.J. Ahmad I. Zainul Abidin N.F. Ali Gamel M.M. 57191706660 37461740800 12792216600 57210155462 57280351300 Cost effectiveness; Fins (heat exchange); Gate dielectrics; Graphene; High-k dielectric; Low-k dielectric; Silica; Silicon on insulator technology; Silicon oxides; Silicon wafers; Threshold voltage; Voltage scaling; Feasible alternatives; Fin field-effect transistors; Fully depleted silicon-on-insulator; Gate-length; MOS-FET; MOSFETs; Performance; PMOS; Taguchi; Technology nodes; FinFET At the 90-nm node, the rate of transistor miniaturization slows down due to challenges in overcoming the increased leakage current (Ioff). The invention of high-k/metal gate technology at the 45-nm technology node was an enormous step forward in extending Moore�s Law. The need to satisfy performance requirements and to overcome the limitations of planar bulk transistor to scales below 22 nm led to the development of fully depleted silicon-on-insulator (FDSOI) and fin field-effect transistor (FinFET) technologies. The 28-nm wafer planar process is the most cost-effective, and scaling towards the sub-10 nm technology node involves the complex integration of new materials (Ge, III-V, graphene) and new device architectures. To date, planar transistors still command >50% of the transistor market and applications. This work aims to downscale a planar PMOS to a 14-nm gate length using La2O3 as the high-k dielectric material. The device was virtually fabricated and electrically characterized using SILVACO. Taguchi L9 and L27 were employed to study the process parameters� variability and interaction effects to optimize the process parameters to achieve the required output. The results obtained from simulation using the SILVACO tool show good agreement with the nominal values of PMOS threshold voltage (Vth) of ?0.289 V � 12.7% and Ioff of less than 10?7 A/�m, as projected by the International Technology Roadmap for Semiconductors (ITRS). Careful control of SiO2 formation at the Si interface and rapid annealing processing are required to achieve La2O3 thermal stability at the target equivalent oxide thickness (EOT). The effects of process variations on Vth, Ion and Ioff were investigated. The improved voltage scaling resulting from the lower Vth value is associated with the increased Ioff due to the improved drain-induced barrier lowering as the gate length decreases. The performance of the 14-nm planar bulk PMOS is comparable to the performance of the FDSOI and FinFET technologies at the same gate length. The comparisons made with ITRS, the International Roadmap for Devices and Systems (IRDS), and the simulated and experimental data show good agreement and thus prove the validity of the developed model for PMOSs. Based on the results demonstrated, planar PMOSs could be a feasible alternative to FDSOI and FinFET in balancing the trade-off between performance and cost in the 14-nm process. � 2021 by the authors. Licensee MDPI, Basel, Switzerland. Final 2023-05-29T09:05:50Z 2023-05-29T09:05:50Z 2021 Article 10.3390/ma14195721 2-s2.0-85116104818 https://www.scopus.com/inward/record.uri?eid=2-s2.0-85116104818&doi=10.3390%2fma14195721&partnerID=40&md5=c09fce74d1bd746abf99a2a0e71a00a2 https://irepository.uniten.edu.my/handle/123456789/25971 14 19 5721 All Open Access, Gold, Green MDPI Scopus
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 Cost effectiveness; Fins (heat exchange); Gate dielectrics; Graphene; High-k dielectric; Low-k dielectric; Silica; Silicon on insulator technology; Silicon oxides; Silicon wafers; Threshold voltage; Voltage scaling; Feasible alternatives; Fin field-effect transistors; Fully depleted silicon-on-insulator; Gate-length; MOS-FET; MOSFETs; Performance; PMOS; Taguchi; Technology nodes; FinFET
author2 57191706660
author_facet 57191706660
Mah S.K.
Ker P.J.
Ahmad I.
Zainul Abidin N.F.
Ali Gamel M.M.
format Article
author Mah S.K.
Ker P.J.
Ahmad I.
Zainul Abidin N.F.
Ali Gamel M.M.
spellingShingle Mah S.K.
Ker P.J.
Ahmad I.
Zainul Abidin N.F.
Ali Gamel M.M.
A feasible alternative to fdsoi and finfet: Optimization of w/la2o3/si planar pmos with 14 nm gate-length
author_sort Mah S.K.
title A feasible alternative to fdsoi and finfet: Optimization of w/la2o3/si planar pmos with 14 nm gate-length
title_short A feasible alternative to fdsoi and finfet: Optimization of w/la2o3/si planar pmos with 14 nm gate-length
title_full A feasible alternative to fdsoi and finfet: Optimization of w/la2o3/si planar pmos with 14 nm gate-length
title_fullStr A feasible alternative to fdsoi and finfet: Optimization of w/la2o3/si planar pmos with 14 nm gate-length
title_full_unstemmed A feasible alternative to fdsoi and finfet: Optimization of w/la2o3/si planar pmos with 14 nm gate-length
title_sort feasible alternative to fdsoi and finfet: optimization of w/la2o3/si planar pmos with 14 nm gate-length
publisher MDPI
publishDate 2023
_version_ 1806424104288387072
score 13.222552