High temperature performance of Si:HfO2 based long channel Double Gate Ferroelectric Junctionless Transistors-Reference-Cited by-同舟云学术

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High temperature performance of Si:HfO2 based long channel Double Gate Ferroelectric Junctionless Transistors

Published:2017-03 Issue: Volume:103 Page:78-84
ISSN:0749-6036
Container-title:Superlattices and Microstructures
language:en
Short-container-title:Superlattices and Microstructures

Author:

Mehta Hema,Kaur Harsupreet

Funder

Government of India

Publisher

Elsevier BV

Subject

Electrical and Electronic Engineering,Condensed Matter Physics,General Materials Science

Reference38 articles.

1. Use of negative capacitance to provide voltage amplification for low power nanoscale devices;Salahuddin;Nano Lett.,2008

2. Examination of the possibility of negative capacitance using ferroelectric materials in solid state electronic devices;Krowne;Nanoletters,2011

3. Nanosecond polarization switching and long retention in a novel MFIS-FET based on ferroelectric HfO2;Müller;IEEE Electron Device Lett.,2012

4. Ferroelectricity in HfO2 enables nonvolatile data storage in 28 nm HKMG;Müller,2012

5. HfO2-based Ferroelectric Field-Effect Transistors with 260 nm channel length and long data retention;Yurchuk,2012

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1. A pathway to improve short channel effects of junctionless based FET’s after incorporating technology boosters: a review;Engineering Research Express;2024-02-26

2. Improved Scalability of Negative Capacitance Junctionless Transistors With Underlap Design;IEEE Transactions on Electron Devices;2023-08

3. Temperature Sensitive Analysis of Junctionless Nanowire Ferroelectric Field Effect Transistor (JNFe- FET) for Enhanced Analog Performance;2023 IEEE Devices for Integrated Circuit (DevIC);2023-04-07

4. Sensitivity Analysis and Design of Negative-Capacitance Junctionless Transistor for High-Performance Applications;IEEE Transactions on Electron Devices;2021-08

5. An Analytical Model Including Interface Traps and Temperature Effects in Negative Capacitance Double Gate Field Effect Transistor;Silicon;2020-08-28

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