scholarly journals Performance Characterization of Schottky Tunneling Graphene Field Effect Transistor at 60 nm Gate Length

2017 ◽  
Vol 46 (7) ◽  
pp. 1089-1095
Author(s):  
Noor Faizah Zainul Abidin ◽  
Ibrahim Ahmad ◽  
Pin Jern Ker ◽  
P. Susthitha Menon
Keyword(s):  
Field Effect ◽  
Field Effect Transistor ◽  
Gate Length ◽  
Performance Characterization ◽  
Graphene Field Effect Transistor ◽  
Effect Transistor

Fabrication and Characterization of Graphene Field Effect Transistor: Study of Interfacial Effects for Device Reliability

2015 ◽  
Vol 36 ◽  
pp. 8-15
Author(s):  
Neetu Prasad ◽  
Anita Kumari ◽  
P.K. Bhatnagar ◽  
P.C. Mathur
Keyword(s):  
Work Function ◽  
Field Effect ◽  
Field Effect Transistor ◽  
Interfacial Effects ◽  
Small Series ◽  
Increase With Increase ◽  
Graphene Field Effect Transistor ◽  
Effect Transistor ◽  
Mos Device

In the present work, we report fabrication and electrical characterization of a back gated graphene field effect transistor (GFET). We have focused our study on the interfacial effect (graphene/SiO2) on the performance of the device. Hysteresis was observed in the drain conductance when measured with respect to dual gate sweep voltage, which increases with increasing sweeping voltage range. The conductance was observed to increase with increase in temperature but there was no reduction in the hysteresis. This proved that temperature annealing could improve the channel conductivity but not the interfacial effects. Further, a metal oxide semiconductor (MOS) device was fabricated with SLG inserted in between the metal and oxide layer and its capacitance-voltage (C-V) characteristics were studied. A small series capacitance (2.1 nF) was observed to be existing in series with the oxide capacitance (4.5 nF) which was attributed to the trap states at the interface of graphene and SiO2­ layer. Also, the flat band voltage was not affected by the incorporation of graphene layer in the MOS device indicating no change in the work function of the metal gate (Cr/Au). This is an advantageous situation where graphene does not alter its work function also being impermeable, restricts the diffusion of metal particles through the SiO2.

scholarly journals Channel length scaling and electrical characterization of graphene field effect transistor (GFET)

2019 ◽  
Vol 15 (2) ◽  
pp. 697
Author(s):  
Reena Sri Selvarajan ◽  
Azrul Azlan Hamzah ◽  
Norliana Yusof ◽  
Burhanuddin Yeop Majlis
Keyword(s):  
Field Effect ◽  
Field Effect Transistor ◽  
Electrical Characterization ◽  
Channel Length ◽  
Short Channel ◽  
Conducting Channel ◽  
Graphene Field Effect Transistor ◽  
Effect Transistor ◽  
Length Scaling

<p>The exclusive monoatomic framework of graphene makes it as an alluring material to be implemented in electronic devices. Thus, using graphene as charge carrying conducting channel material in Field Effect Transistors (FET) expedites the opportunities for production of ultrasensitive biosensors for future device applications. However, performance of GFET is influenced by various parameters, particularly by the length of conducting channel. Therefore, in this study we have investigated channel length scaling in performance of graphene field effect transistor (GFET) via simulation technique using Lumerical DEVICE software. The performance was analyzed based on electrical characterization of GFET with long and short conducting channels. It proves that conducting channel lengths have vast effect on ambipolar curve where short channel induces asymmetry in transfer characteristics curve where the n-branch is suppressed. Whereas for output characteristics, the performance of GFET heavily degraded as the channel length is reduced in short channels of GFET. Therefore, channel length scaling is a vital parameter in determining the performance of GFET in various fields, particularly in biosensing applications for ultrasensitive detection.</p>

scholarly journals Ab initio perspective of ultra-scaled CMOS from 2D-material fundamentals to dynamically doped transistors

2021 ◽  
Vol 5 (1) ◽  
Author(s):  
Aryan Afzalian
Keyword(s):  
Field Effect ◽  
High Performance ◽  
Field Effect Transistor ◽  
High Mobility ◽  
Complementary Metal Oxide Semiconductor ◽  
Oxide Semiconductor ◽  
Grand Challenge ◽  
Gate Length ◽  
Delay Performance ◽  
Effect Transistor

AbstractUsing accurate dissipative DFT-NEGF atomistic-simulation techniques within the Wannier-Function formalism, we give a fresh look at the possibility of sub-10-nm scaling for high-performance complementary metal oxide semiconductor (CMOS) applications. We show that a combination of good electrostatic control together with high mobility is paramount to meet the stringent roadmap targets. Such requirements typically play against each other at sub-10-nm gate length for MOS transistors made of conventional semiconductor materials like Si, Ge, or III–V and dimensional scaling is expected to end ~12 nm gate-length (pitch of 40 nm). We demonstrate that using alternative 2D channel materials, such as the less-explored HfS2 or ZrS2, high-drive current down to ~6 nm is, however, achievable. We also propose a dynamically doped field-effect transistor concept, that scales better than its MOSFET counterpart. Used in combination with a high-mobility material such as HfS2, it allows for keeping the stringent high-performance CMOS on current and competitive energy-delay performance, when scaling down to virtually 0 nm gate length using a single-gate architecture and an ultra-compact design (pitch of 22 nm). The dynamically doped field-effect transistor further addresses the grand-challenge of doping in ultra-scaled devices and 2D materials in particular.

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