Designing of Cylindrical Surrounding Double-Gate MOSFETs at Nanotechnology Scale from Double-Gate MOSFETs: Advancements of Silicon Semiconductor Devices

Gowthaman, Naveenbalaji; Srivastava, Viranjay

Designing of Cylindrical Surrounding Double-Gate MOSFETs at Nanotechnology Scale from Double-Gate MOSFETs: Advancements of Silicon Semiconductor Devices

Gowthaman, Naveenbalaji and Srivastava, Viranjay (2026) Designing of Cylindrical Surrounding Double-Gate MOSFETs at Nanotechnology Scale from Double-Gate MOSFETs: Advancements of Silicon Semiconductor Devices. Journal of Electrical Engineering & Technology. ISSN 1975-0102

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Official URL: https://link.springer.com/article/10.1007/s42835-0...

Abstract

This research work addresses the critical need for advanced semiconductor devices in radio frequency (RF) applications by investigating Cylindrical Surrounding Double-Gate (CSDG) MOSFETs with La₂O₃ oxide. The work employs comprehensive modeling approaches, including Auger recombination, Band-To-Band Tunneling (BTBT), and energy transport models, analyze device performance. Key findings demonstrate a symmetric electron density distribution, peaking at the channel center with a gradual decline towards the edges, confirming superior electrostatic control. The CSDG MOSFET achieves exceptional performance metrics: subthreshold swing values of 20.0–23.5 mV/decade and an ION/IOFF ratio of 1.89 × 104, significantly outperforming conventional designs by 65% and 300% respectively. Energy-transmission analysis reveals an inverse exponential correlation T(E) = 0·85e-0·02E, with transmission coefficient decreasing from 0.8 at 10 eV to 0.05 at 200 eV. The novel La₂O₃/AlGaAs material system provides enhanced electrostatic control, reduced short-channel effects, and superior thermal management compared to SiO₂ and HfO₂ systems, making CSDG MOSFETs promising candidates for next-generation 5G/6G applications and low-power IoT devices.

Item Type:	Article
Identification Number:	10.1007/s42835-026-02589-z
Dates:	Date Event 8 January 2026 Accepted 30 January 2026 Published Online
Uncontrolled Keywords:	CSDG MOSFET, Electrostatic control, High-frequency performance, Semiconductor devices, Shortchannel effects, Nanotechnology, VLSI
Subjects:	CAH10 - engineering and technology > CAH10-01 - engineering > CAH10-01-08 - electrical and electronic engineering
Divisions:	Architecture, Built Environment, Computing and Engineering > Engineering
Depositing User:	Gemma Tonks
Date Deposited:	25 Feb 2026 14:01
Last Modified:	25 Feb 2026 14:01
URI:	https://www.open-access.bcu.ac.uk/id/eprint/16888