Simulation of Macro-Compact Model of Graphene-based Three-Branch Nano-Junction

Gated-graphene three-branch nano-junction (G-GTBJ) has been investigated as a promising ballistic device for various applications. Device modelling of G-GTBJ is beneficial for investigating its basic operation both in single device and in circuit level. Simulation of device design model using a dedi...

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Main Authors: Kalantari, Alireza, Rahman, Shaharin Fadzli Abd, Manaf Hashim, Abdul
Format: Conference Proceeding
Language:English
Subjects:
device simulation
graphene
Integrated circuit modeling
Logic gates
macrocompact model
Modulation
Nanoscale devices
Rectifiers
Temperature
Temperature dependence
three-branch nano-junction
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Rahman, Shaharin Fadzli Abd
Manaf Hashim, Abdul
description Gated-graphene three-branch nano-junction (G-GTBJ) has been investigated as a promising ballistic device for various applications. Device modelling of G-GTBJ is beneficial for investigating its basic operation both in single device and in circuit level. Simulation of device design model using a dedicated simulator such as TCAD simulator is only practical in evaluating the operation of a single device. This paper evaluated a macrocompact model equivalent circuit and the simulation of the G-GTBJ was done using a general electronic circuit simulator. For validation of the simulation, the obtained results were compared with the reported work that used a TCAD simulator. The investigated macro model produces the characteristics that are in good agreement with the TCAD-based simulation work. The dependences of G-GTBJ's characteristics on carrier mobility, empirical parameter of Fsat, temperature, branch length and width were analysed. Branch length and carrier mobility showed significant effects on the simulated characteristics. The macro model was also used to demonstrate the operation of G-GTBJ based rectifier and logic gate circuit. The proposed approach seems to offer much simpler solution for the investigation of other G-GTBJ based device and logic circuit, and is expected to be beneficial for larger circuit-level simulation.
doi_str_mv 10.1109/RSM59033.2023.10326917
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Device modelling of G-GTBJ is beneficial for investigating its basic operation both in single device and in circuit level. Simulation of device design model using a dedicated simulator such as TCAD simulator is only practical in evaluating the operation of a single device. This paper evaluated a macrocompact model equivalent circuit and the simulation of the G-GTBJ was done using a general electronic circuit simulator. For validation of the simulation, the obtained results were compared with the reported work that used a TCAD simulator. The investigated macro model produces the characteristics that are in good agreement with the TCAD-based simulation work. The dependences of G-GTBJ's characteristics on carrier mobility, empirical parameter of Fsat, temperature, branch length and width were analysed. Branch length and carrier mobility showed significant effects on the simulated characteristics. The macro model was also used to demonstrate the operation of G-GTBJ based rectifier and logic gate circuit. 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subjects device simulation
graphene
Integrated circuit modeling
Logic gates
macrocompact model
Modulation
Nanoscale devices
Rectifiers
Temperature
Temperature dependence
three-branch nano-junction
title Simulation of Macro-Compact Model of Graphene-based Three-Branch Nano-Junction
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