Non-Equilibrium Green Function-based Verilog-A Graphene Nanoribbon Model

Jiang, Y.; Cucu Laurenciu, N.; Cotofana, S.D.

Non-Equilibrium Green Function-based Verilog-A Graphene Nanoribbon Model

Conference paper (2019)

Authors

Y. Jiang Computer Engineering -

N. Cucu Laurenciu Computer Engineering -

S.D. Cotofana Computer Engineering -

Research Group

Computer Engineering () (TU Delft)

Graphene NEGF GNR Carbon- Nanoelectronics Spice Model Verilog-A

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http://resolver.tudelft.nl/uuid:2d2d97c8-babf-45aa-a959-369562152f56

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Published Date

2019

Language

English

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Faculty

Electrical Engineering, Mathematics and Computer Science

Department

Quantum & Computer Engineering

Research Group

Computer Engineering

Abstract

Graphene, due to its wealth of remarkable electronic properties, emerged as a potent post-Si forerunner for nanoelectronics. To enable the exploration and evaluation of potential graphene-based circuit designs, we propose a fast and accurate Verilog-A physics-based model of a 5-terminal trapezoidal Quantum Point Contact (QPC) Graphene Nano-Ribbon (GNR) structure with parametrizable geometry. The proposed model computes the GNR conductance based on the Non-Equilibrium Green's Function (NEGF)-Landauer formalism, via a Simulink model called from within the Verilog-A model. Furthermore, model accuracy and versatility are demonstrated by means of Simulink assisted Cadence Spectre simulation of a simple test case GNR-based circuit and a GNR-based 2-input XOR gate.

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