The Effect of Bilayer Graphene Nanoribbon Geometry on Schottky‐Barrier Diode Performance

Graphene is one of the carbon allotropes which is a single atom thin layer with sp2hybridized and two-dimensional (2D) honeycomb structure of carbon. As an outstanding material exhibiting unique mechanical, electrical, and chemical characteristics including high strength, high conductivity, and high surface area, graphene has earned a remarkable position in today’s experimental and theoretical studies as well as industrial applications. One such application incorporates the idea of using graphene to achieve accuracy and higher speed in detection devices utilized in cases where gas sensing is required. Although there are plenty of experimental studies in this field, the lack of analytical models is felt deeply. To start with modelling, the field effect transistor- (FET-) based structure has been chosen to serve as the platform and bilayer graphene density of state variation effect byNO2injection has been discussed. The chemical reaction between graphene and gas creates new carriers in graphene which cause density changes and eventually cause changes in the carrier velocity. In the presence ofNO2gas, electrons are donated to the FET channel which is employed as a sensing mechanism. In order to evaluate the accuracy of the proposed models, the results obtained are compared with the existing experimental data and acceptable agreement is reported.

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“…The tight-binding method has been used to calculate the biased energy of BLGs, which indicates energy dispersion of BLG as follows [29,30]:…”

Section: The Proposed Modelmentioning

confidence: 99%

Bilayer Graphene Application on NO₂ Sensor Modelling

Akbari

Yusof

Ahmadi

et al. 2014

Journal of Nanomaterials

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Investigation of Optoelectronic Properties of Organic Semiconductor Tetracyaoquinodimethane Based Heterostructures

Avcı

Hussaini

Erdal

et al. 2021

Selçuk Üniversitesi Fen Fakültesi Fen Dergisi

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Recently, interfacial layer such as metal oxide, insulator and polymer have been used by scientists between the metal and semiconductor to increase the stability of the metal-semiconductor heterojunctions. These materials have been varied according to their usage aims. In this study, graphene nanoribbons (GNR) and 7,7,8,8 Tetracyanoquinodimethane (TCNQ, C12H4N4) layer has been used as interfacial layer between the metal and semiconductor for photodiode applications. The TCNQ layer collects and extracts more electrons in the interface of the device and is used as electron acceptor material for organic solar cells. Herein, we fabricated Al/p-Si/Al, Al/p-Si/TCNQ/Al and Al/p-Si/TCNQ:GNR/Al heterojunctions by physical vapor deposition technique. I-V measurements has been employed under dark and various light illumination conditions to show dielectric properties of the fabricated heterojunctions. From current-voltage characteristics, we calculated the electronic parameters such as ideality factor, barrier heights, series resistances and rise times. It can be concluded from overall results that TCNQ and TCNQ:GNR layers had a major impact on quality and can be considered as quite proper materials for optoelectronic applications.

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The Effect of Bilayer Graphene Nanoribbon Geometry on Schottky‐Barrier Diode Performance

Cited by 2 publications

References 39 publications

Bilayer Graphene Application on NO₂ Sensor Modelling

Bilayer Graphene Application on NO₂ Sensor Modelling

Investigation of Optoelectronic Properties of Organic Semiconductor Tetracyaoquinodimethane Based Heterostructures

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The Effect of Bilayer Graphene Nanoribbon Geometry on Schottky‐Barrier Diode Performance

Cited by 2 publications

References 39 publications

Bilayer Graphene Application on NO2 Sensor Modelling

Bilayer Graphene Application on NO2 Sensor Modelling

Investigation of Optoelectronic Properties of Organic Semiconductor Tetracyaoquinodimethane Based Heterostructures

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Product

Resources

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Bilayer Graphene Application on NO₂ Sensor Modelling

Bilayer Graphene Application on NO₂ Sensor Modelling