Nano-electronic Simulation Software (NESS): a flexible nano-device simulation platform

Berrada, S., Carrillo-Nunez, H., Lee, J., Medina Bailon, C., Dutta, T. , Badami, O., Adamu-Lema, F., Thirunavukkarasu, V., Georgiev, V. and Asenov, A. (2020) Nano-electronic Simulation Software (NESS): a flexible nano-device simulation platform. Journal of Computational Electronics, 19, pp. 1031-1046. (doi: 10.1007/s10825-020-01519-0)

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Abstract

The aim of this paper is to present a flexible and open-source multi-scale simulation software which has been developed by the Device Modelling Group at the University of Glasgow to study the charge transport in contemporary ultra-scaled Nano-CMOS devices. The name of this new simulation environment is Nano-electronic Simulation Software (NESS). Overall NESS is designed to be flexible, easy to use and extendable. Its main two modules are the structure generator and the numerical solvers module. The structure generator creates the geometry of the devices, defines the materials in each region of the simulation domain and includes eventually sources of statistical variability. The charge transport models and corresponding equations are implemented within the numerical solvers module and solved self-consistently with Poisson equation. Currently, NESS contains a drift–diffusion, Kubo–Greenwood, and non-equilibrium Green’s function (NEGF) solvers. The NEGF solver is the most important transport solver in the current version of NESS. Therefore, this paper is primarily focused on the description of the NEGF methodology and theory. It also provides comparison with the rest of the transport solvers implemented in NESS. The NEGF module in NESS can solve transport problems in the ballistic limit or including electron–phonon scattering. It also contains the Flietner model to compute the band-to-band tunneling current in heterostructures with a direct band gap. Both the structure generator and solvers are linked in NESS to supporting modules such as effective mass extractor and materials database. Simulation results are outputted in text or vtk format in order to be easily visualized and analyzed using 2D and 3D plots. The ultimate goal is for NESS to become open-source, flexible and easy to use TCAD simulation environment which can be used by researchers in both academia and industry and will facilitate collaborative software development.

Item Type:Articles
Status:Published
Refereed:Yes
Glasgow Author(s) Enlighten ID:Dutta, Dr Tapas and Carrillo-Nunez, Dr Hamilton and Asenov, Professor Asen and Lee, Jaehyun and Medina Bailon, Miss Cristina and Berrada, Dr Salim and Thirunavukkarasu, Dr Vasanthan and Badami, Mr Oves and Georgiev, Dr Vihar and Adamu-Lema, Dr Fikru
Authors: Berrada, S., Carrillo-Nunez, H., Lee, J., Medina Bailon, C., Dutta, T., Badami, O., Adamu-Lema, F., Thirunavukkarasu, V., Georgiev, V., and Asenov, A.
College/School:College of Science and Engineering > School of Engineering > Electronics and Nanoscale Engineering
Journal Name:Journal of Computational Electronics
Publisher:Springer
ISSN:1569-8025
ISSN (Online):1572-8137
Published Online:05 June 2020
Copyright Holders:Copyright © 2020 The Authors
First Published:First published in Journal of Computational Electronics 19:1031-1046
Publisher Policy:Reproduced under a Creative Commons License

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Project CodeAward NoProject NamePrincipal InvestigatorFunder's NameFunder RefLead Dept
172265SUPERAID7Asen AsenovEuropean Commission (EC)Asenov, Professor AsenENG - Electronics & Nanoscale Engineering
302377Quantum Simulator for Entangled Electronics (QSEE)Vihar GeorgievEngineering and Physical Sciences Research Council (EPSRC)EP/S001131/1ENG - Electronics & Nanoscale Engineering
173715Quantum Electronics Device Modelling (QUANTDEVMOD)Vihar GeorgievEngineering and Physical Sciences Research Council (EPSRC)EP/P009972/1ENG - Electronics & Nanoscale Engineering