Method for calculating radiative energy transfer in the “back and forth” approximation

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This paper presents a method for calculating the radiative energy transfer in the back and forth approximation for the case of cylindrically symmetric currents. The key element of the method is the scheme for calculating radiative heat transfer in a medium with opacity that strongly varies in space and time. The paper discusses the possibility of improving accuracy of solving a difference equations’ system by making the approximation of absorption coefficients more accurate. The numerical technique proposed for multi-parameter computing experiments makes it possible to obtain the radiation energy density as a quadrature of plasma opacity and emissivity. In two-temperature model of gas dynamics and magnetohydrodynamics, this determines the contribution of radiative heat transfer into the energy balance of the plasma electronic component. Numerical comparison of the proposed method with some diffusion methods was implemented via test examples simulating spatial inhomogeneity of the radiation field. It is shown that the calculations performed according to the methodology considered in this paper, give a qualitatively correct match with the analytical solution of the problem, in contrast to calculations performed by the method of diffuse approximation. The obvious advantage of the back and forth approximation is that integrality is inherent in its structure.

Sobre autores

Alexander Krukovskiy

Keldysh Institute of Applied Mathematics of Russian Academy of Sciences

Email: alexander-krukovskiy@yandex.ru
ORCID ID: 0000-0003-4188-6904

D. Sci. (Physics and Mathematics)

Rússia, 4 Miusskaya Sq., Moscow 125047, Russia

Marina Ladonkina

Keldysh Institute of Applied Mathematics of Russian Academy of Sciences

Autor responsável pela correspondência
Email: ladonkina@imamod.ru
ORCID ID: 0000-0001-7596-1672

Ph. D. (Physics andMathematics),  Senior Researcher

Rússia, 4 Miusskaya Sq., Moscow 125047, Russia

Yuri Poveshchenko

Keldysh Institute of Applied Mathematics of Russian Academy of Sciences

Email: hecon@mail.ru
ORCID ID: 0000-0001-9211-9057

Dr. Sci. (Physics and Mathematics), Leading Researcher

Rússia, 4 Miusskaya Sq., Moscow 125047, Russia

Igor Popov

Keldysh Institute of Applied Mathematics of Russian Academy of Sciences

Email: piv2964@mail.ru
ORCID ID: 0000-0002-7347-8174

Ph. D. (Physics and Mathematics), Senior Researcher

Rússia, 4 Miusskaya sq., Moscow, 125047

Bibliografia

  1. S. B. Hansen, M. R. Gomez, A. B. Sefkow, S. A. Slutz, D. B. Sinars, K. D. Hahn, E. C. Harding, P. F. Knapp, P. F. Schmit, T. J. Awe, R. D. McBride, C. A. Jennings, M. Geissel, A. J. Harvey-Thompson, K. J. Peterson, D. C. Rovang, G. A. Chandler, G. W. Cooper, M. E. Cuneo, M. C. Herrmann, M. H. Hess, O. Johns, D. C. Lamppa, M.
  2. R. Martin, J. L. Porter, G. K. Robertson, G. A. Rochau, C. L. Ruiz, M. E. Savage, I. C. Smith, W. A. Stygar, R. A. Vesey, B. E. Blue, D. Ryutov, D. G. Schroen, K. Tomlinson, “Diagnosing magnetized liner inertial fusion experiments on Z”, Physics of Plasmas, 22 (2015). DOI: https://doi.org/10.1063/1.4921217
  3. A. J. Gonsalves, K. Nakamura, J. Daniels, C. Benedetti, C. Pieronek, T. C. H. de Raadt, S. Steinke, J. H. Bin, S. S. Bulanov, J. van Tilborg, C. G. R. Geddes, C. B. Schroeder, Cs. TOth, E. Esarey, K. Swanson, L. Fan-Chiang, G. Bagdasarov, N. Bobrova, V. Gasilov, G. Korn, P. Sasorov, W. P. Leemans, “Petawatt laser
  4. guiding and electron beam acceleration to 8 GeV in a laser-heated capillary discharge waveguide”, Physical Review Letters, 122:8 (2019).
  5. Ya. B. Zeldovich, Yu. P. Raiser, Physics of shock waves and high-temperature hydrodynamic phenomena, Fismatlit Publ., Moscow, 2008 (In Russ.), 653 p.
  6. M. N. Oscik, Complex heat transfer, Mir Publ., Moscow, 1976 (In Russ.), 305 p.
  7. V. A. Gasilov, S. V. Zakharov, V. P. Smirnov, “Generation of intense radiation fluxes and megabar pressures in liner systems”, Letters to the JETPh, 53:2 (1991), 83–86 (In Russ.).
  8. V. A. Gasilov, S. V. Zakharov, A. Yu. Krukovsky, K. V. Skorovarov, “Generation of intense radiation fluxes and megabar shock waves by compressing liners”, Plasma Physics, 21:5 (1995), 399–406 (In Russ.).
  9. V. A. Gasilov, A. Yu. Krukovsky, “On the calculation of radiant heat transfer in a composite Z-pinch”, Matem. modelirovaniye, 34:9 (2022), 21–36 (In Russ.). DOI: https://doi.org/10.20948/mm-2022-09-02
  10. B. N. Chetverushkin, Mathematical simulation of radiating gas dynamics problems, Nauka Publ., Moscow, 1985 (In Russ.), 304 p.
  11. A. D. Rekin, “Radiation transfer equations in the Schuster-Schwarzschild approximation for problems with spherical and cylindrical symmetry”, TVT, 16:4 (1978), 811–818 (In Russ.).
  12. G. S. Romanov, A. S. Smetannikov, “Numerical modeling of a layered pulsed discharge taking into account the transfer of radiation energy”, JTPh, 52:9 (1982), 1756–1762 (In Russ.).

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Declaração de direitos autorais © Krukovskiy A.J., Ladonkina M.E., Poveshchenko Y.A., Popov I.V., 2022

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