Enviar artigo por via de e-mail Simulation the behavior of a two-level quantum system using scalable regular grids
- Autores: Panferov A.D.1, Posnova N.V.1, Ulyanova A.A.1
-
Afiliações:
- Saratov State University
- Edição: Volume 14, Nº 2 (2023)
- Páginas: 27-47
- Seção: Articles
- URL: https://bakhtiniada.ru/2079-3316/article/view/259979
- DOI: https://doi.org/10.25209/2079-3316-2023-14-2-27-47
- ID: 259979
Citar
Texto integral
Resumo
The paper demonstrates a method for constructing a grid with a changing scale for modeling the behavior of a two-level quantum system. The method was proposed and implemented in relation to the problem of reproducing the behavior of graphene in external electric fields using the quantum kinetic equation. A direct numerical solution of the kinetic equation makes it possible to accurately and completely reproduce the behavior of models of this type. But a large amount of computation is required for a good quality reproduction of the observed parameters. The complexity of the problem is directly proportional to the number of grid nodes in the two-dimensional space of states, in each of which a system of ordinary differential equations is solved to reproduce the evolution of the population of the upper energy level. The study of the behavior of the model made it possible to develop and implement an economical procedure for constructing a computational grid, which ensures the localization of the region of formation of excited states and exact reproduction of the observed process parameters.
Sobre autores
Anatolii Panferov
Saratov State University
Autor responsável pela correspondência
Email: panferovad@sgu.ru
ORCID ID: 0000-0003-2332-0982
Natalia Posnova
Saratov State University
Email: natalie.posnova@gmail.com
ORCID ID: 0000-0003-1259-1867
Anastasia Ulyanova
Saratov State University
Email: ulyanova.nastiya@yandex.ru
ORCID ID: 0000-0001-9519-9822
Bibliografia
- Novoselov K. S., Geim A. K., Morozov S. V., Jiang D., Katsnelson M. I., Grigorieva I. V., Dubonos S. V., Firsov A. A.. “Two-dimensional gas of massless dirac fermions in graphene”, Nature, 438 (2005), pp. 197–200.
- Castro Neto A. H., Guinea F., Peres N. M. R., Novoselov K. S., Geim A. K.. “The eletronic properties of graphene”, Rev. Mod. Phys, 81:1 (2009), 109.
- Glazov M. M., Ganichev S. D.. “High frequency electric field induced nonlinear effects in graphene”, Physics Reports, 535:3 (2014), pp. 101–138.
- Bowlan P., Martinez-Moreno E., Reimann K., Elsaesser T., Woerner M.. “Ultrafast terahertz response of multilayer graphene in the nonperturbative regime”, Phys. Rev. B, 89 (2014), 041408.
- Baudisch M., Marini A., Cox J. D., Zhu T., Silva F., Teichmann S., Massicotte M., Koppens F., Levitov L. S., García de Abajo F. J., Biegert J.. “Ultrafast nonlinear optical response of Dirac fermions in graphene”, Nature Communications, 9 (2018), 1018, 6 pp.
- Zi-Yu Chen, Rui Gin. “Circularly polarized extreme ultraviolet high harmonic generation in graphene”, Optics Express, 27:3 (2019), pp. 3761–3770.
- Wenwen Mao, Angel Rubio, Shunsuke A. Sato. “Terahertz-induced high-order harmonic generation and nonlinear charge transport in graphene”, Phys. Rev. B, 106 (2022), 024313.
- Soonyoung Cha, Minjeong Kim, Youngjae Kim, Shinyoung Choi, Sejong Kang, Hoon Kim, Sangho Yoon, Gunho Moon, Taeho Kim, Ye Won Lee, Gil Young Cho, Moon Jeong Park, Cheol-Joo Kim, Kim B. J., JaeDong Lee, Moon-Ho Jo, Jonghwan Kim. “Gate-tunable quantum pathways of high harmonic generation in graphene”, Nature Communications, 13 (2022), 6630, 10 pp.
- Smolyansky S. A., Churochkin D. V., Dmitriev V. V., Panferov A. D., K.ampfer B.. “Residual currents generated from vacuum by an electric field pulse in 2+1 dimensional QED models”, EPJ Web of Conferences, 138 (2017), 06004, 5 pp.
- Panferov A. D., Smolyansky S. A., Blaschke D. B., N. Gevorgyan T.. “Comparing two different descriptions of the I-V characteristic of graphene: theory and experiment”, EPJ Web of Conferences, 204 (2019), 06008, 6 pp.
- Smolyansky S. A., Panferov A. D., Blaschke D. B., Gevorgyan N. T.. “Nonperturbative kinetic description of electron-hole excitations in graphene in a time dependent electric field of arbitrary polarization”, Particles, 2:2 (2019), pp. 208–230.
- Панферов А. Д., Маханьков А. В., Трунов А. А.. «Использование адаптивной сетки на основе квадродерева для моделирования конечного состояния квантово-полевой системы при импульсном внешнем воздействии», Программные системы: теория и приложения, 11:1 (2020), с. 79–92 A. D. Panferov, A. V. Makhankov, A. A. Trunov.
- Панферов А. Д., Новиков Н. А., Трунов А. А.. «Simulate the behavior of graphene in external electric fields», Программные системы: теория и приложения, 12 (2021) (in Russian).
Arquivos suplementares
