Simulation the response of graphene to an external electric field using the exact tight-binding model

Nikolay Novikov; Anatolii Panferov; Anastasiya Ulyanova

Program Systems:
Theory and Applications

ISSN 2079-3316

12+

Bilingual electronic scientific Electronic scientific journal of the Ailamazyan Program System Institute of the Ailamazyan PSI of PSI of Russian Academy of Science of RAS

Volume 15 (2024) . Issue 3 (62) . Paper No. 1 (448)

Computational science

Research Article

DOI

10.25209/2079-3316-2024-15-3-3-22

Simulation the response of graphene to an external electric field using the exact tight-binding model

Anatolii Panferov¹, Nikolay Novikov², Anastasiya Ulyanova³

^1-3	Saratov State University, Saratov, Russia
¹	panferovad@sgu.ru

Abstract. Numerical simulation of the interaction of electromagnetic radiation with graphene allows us to reproduce fast nonlinear processes and their observed manifestations. The paper presents the results obtained in the process of developing a software solution for calculating the observed parameters of such processes.

In graphene physics, the massless fermion approximation is classical. However, in the study of processes with high energy density, model based on this approximation are beyond the limits of their applicability and the results obtained on their basis can not be considered reliable. To solve this problem, a transition to a substantially more accurate model based on a strict account of the nearest-neighbor interaction in the crystal lattice (tight-binding model) has been made.

Comparative testing of these two models shows that at low energy characteristics of the external perturbation the results coincide. However, as the energy characteristics of the affecting electromagnetic field increase, the divergence of the results becomes apparent and grows.

The new exact model has a more complex mathematical formulation and requires more computational resources. When using the same hardware configuration it is expressed in the increase of counting time. Relative and absolute values for a number of examples are given.

The obtained results allow us to expand the range of parameters for modeling of nonlinear processes in the considered material, for example, generation of high-frequency harmonics and ensure its reliability. (In Russian).

Keywords: numerical simulation, nonlinear processes, quantum kinetic equation, tight-binding model

MSC-2020

65Z05; 81-04; 81T40 MSC-2020 65-XX: Numerical analysis
MSC-2020 65Zxx: Applications to the sciences
MSC-2020 81-XX: Quantum theory
MSC-2020 81-04: Software, source code, etc. for problems pertaining to quantum theory

MSC-2020 65-XX: Numerical analysis
MSC-2020 65Zxx: Applications to the sciences
MSC-2020 81-XX: Quantum theory
MSC-2020 81-04: Software, source code, etc. for problems pertaining to quantum theory

Acknowledgments: The study was supported by the Russian Science Foundation grant No. 23-21-00047, https://rscf.ru/project/23-21-00047/

For citation: Anatolii Panferov, Nikolay Novikov, Anastasiya Ulyanova. Simulation the response of graphene to an external electric field using the exact tight-binding model. Program Systems: Theory and Applications, 2024, 15:3, pp. 3–22. (In Russ.). https://psta.psiras.ru/2024/3_3-22.

Full text of article (PDF): https://psta.psiras.ru/read/psta2024_3_3-22.pdf.

The article was submitted 01.04.2024; approved after reviewing 29.05.2024; accepted for publication 09.08.2024; published online 10.09.2024.

2024

Editorial address: Ailamazyan Program Systems Institute of the Russian Academy of Sciences, Peter the First Street 4«a», Veskovo village, Pereslavl area, Yaroslavl region, 152021 Russia; Phone: +7(4852) 695-228; E-mail: ; Website: http://psta.psiras.ru

Computational science

Research Article

Simulation the response of graphene to an external electric field using the exact tight-binding model

Anatolii Panferov1, Nikolay Novikov2, Anastasiya Ulyanova3

Anatolii Panferov¹, Nikolay Novikov², Anastasiya Ulyanova³