STELLAR WIND OF COMPONENTS OF DETACHED BINARY SYSTEMS

Cover Page

Cite item

Full Text

Open Access Open Access
Restricted Access Access granted
Restricted Access Subscription or Fee Access

Abstract

The paper is devoted to the consideration of the role of the donor stellar wind in the matter exchange between the components of detached binary systems. A classification of close binary systems with interacting components is proposed. A list of potential donors and accretors of such systems, including X-ray binary and symbiotic stars, is given. Analytical tasks have been completed to evaluate the conditions and efficiency of interaction through the stellar wind, a criterion was found for maintaining the self-induced stellar wind of X-ray binaries, and a condition for the formation of an accretion disk during accretion of stellar wind matter by a compact accretor. Three-dimensional gas dynamic models of component interaction are constructed for the five initial velocities of the stellar wind using the example of Sco X-1 type systems. The simulation results are illustrated by pictures of streamlines, temperature distribution, and wind gas densities in the orbital and frontal planes. Model focusing of the donor wind flow by the accretor is confirmed by the observed phase X-ray light curve of Vela X-1.

About the authors

A. V. Tutukov

Institute of Astronomy of the Russian Academy of Sciences

Moscow, Russia

A. V. Sobolev

Institute of Astronomy of the Russian Academy of Sciences

Email: asobolev@inasan.ru
Moscow, Russia

References

  1. A.I. Maceau, A.B. Tymykoe, Эволюция звезд: теория и наблюдения (M: Наука, 1988).
  2. A.M. Черепащук, Тесные двойные звезды, том I, II (М.: Физматлит, 2013).
  3. Д.В. Бисикало, A.T. Жилкин, A.A. Боярчук, Газодинамика тесных двойных звезд (М.: Физматлит, 2013).
  4. A.V. Tutukov, L.R. Yungelson, and I. Iben, Jr., 386, 197 (1992).
  5. V.M. Lipunov, K.A. Postnov, M.E. Prokhorov, and E.Yu. Osminkin, Letters 423, L121 (1994).
  6. L. Oskinova, T. Bulik, and A. Gomez-Moran, Astron. and Astrophys. 613, id. 10 (2018).
  7. A.V. Tutukov and L.R. Yungelson, 12, 342 (1976).
  8. M. MacLeod, A. Oklopcic, F. Nail, and D. Linssen, arXiv:2411.12895 [astro-ph.EP] (2024).
  9. G. Hill, A. Moffat, and N. St-Louis, Monthly Not. Roy. Astron. Soc. 335(4), 1069 (2002).
  10. G.E. Romero, A.T. Okazaki, M. Orellana, and S.P. Owocki, Astron. and Astrophys. 474(1), 15 (2007).
  11. E.R. Parkin and J.M. Pittard, Monthly Not. Roy. Astron. Soc. 388(3), 1047 (2008).
  12. D.V. Bisikalo, A.A. Boyarchuk, E.Yu. Kilpio, N.A. Tomov, and M.T. Tomova, Astron. Rep. 50(9), 722 (2006).
  13. D.V. Bisikalo, A.A. Boyarchuk, O.A. Kuznetsov, Yu.P. Popov, and V.M. Chechetkin, Astron. Rep. 38(4), 494 (1994).
  14. A. Skopal and Z. Carikova, Astron. and Astrophys. 573, id. A8 (2015).
  15. J.M. Pittard and S.M. Dougherty, Monthly Not. Roy. Astron. Soc. 372(2), 801 (2006).
  16. A. Taani, S. Karino, L. Song, C. Zhang, and S. Chaty, Publ. Astron. Soc. Australia 39, id. e040 (2022).
  17. J.M. Pittard and E.R. Parkin, Monthly Not. Roy. Astron. Soc. 403(4), 1657 (2010).
  18. A.B. Tymykoe, A.M. Черепащук, Успехи физ. наук 190(3), 225 (2020).
  19. A.V. Tutukov, Astron. Rep. 67(9), 867 (2023).
  20. C.L. Ransome and V.A. Villar, arXiv:2409.10596 [astro-ph.HE] (2024).
  21. A.B. Tymykoe, Научные информации астрон. совета АН СССР 11, 62 (1969).
  22. I. Iben, Jr. and A.V. Tutukov, 284, 719 (1984).
  23. I. Iben, Jr., A.V. Tutukov, and A.V. Fedorova, 486(2), 955 (1997).
  24. D. Baron and H. Netzer, Monthly Not. Roy. Astron. Soc. 486(3), 4290 (2019).
  25. I.A. Shaposhnikov, A.M. Cherepashehuk, A.V. Dodin, and K.A. Postnov, Astron. and Astrophys. 683, id. L17 (2024).
  26. K. Rochowicz and A. Niedzielski, Astron. and Astrophys. 45, 307 (1995).
  27. S. Karino, Monthly Not. Roy. Astron. Soc. 507(1), 1002 (2021).
  28. A.V. Tutukov and A.V. Fedorova, Astron. Rep. 51(10), 847 (2007).
  29. P. Harmanec, D.V. Bisikalo, A.A. Boyarchuk, and O.A. Kuznetsov, Astron. and Astrophys. 396, 937 (2002).
  30. M. Niwano, M.M. Fausnaugh, R.M. Lau, K. De, et al., arXiv:2409.09581 [astro-ph.SR] (2024).
  31. J. Kritika and J. Kubát, Astron. and Astrophys. 377, 175 (2001).
  32. J.S. Vink, Astron. and Astrophys. 615, id. A119 (2018).
  33. M. Shoda, B.D.G. Chandran, and S.R. Cranmer, 915(1), id. 52 (2021).
  34. A. Skumanich, C. Smythe, and E.N. Frazier, Bull. Amer. Astron. Soc. 4, 391 (1972).
  35. A.V. Tutukov, Astron. and Astrophys. 70, 57 (1978).
  36. K. Davidson and J.P. Ostriker, 179, 585 (1973).
  37. De-Fu Bu and F. Yuan, arXiv:2409.01664 [astro-ph. HE] (2024).
  38. E. Boettcher and E. Hodges-Kluck, arXiv:2408.15327 [astro-ph.GA] (2024).
  39. H.H. Loose, E. Kruegel, and A. Tutukov, Astron. and Astrophys. 105(2), 342 (1982).
  40. K.K. Gupta, C. Ricci, M.J. Temple, A. Tortosa, et al., arXiv:2409.12239 [astro-ph.GA] (2024).
  41. S. Kimbrell and A. Reines, arXiv:2409.10630 [astro-ph. GA] (2024).
  42. D. Semenov, Th. Henning, Ch. Helling, M. Ilgner, and E. Sedlmayr, Astron. and Astrophys. 410, 611 (2003).
  43. A.F. Kholiygin, V.F. Bratsev, and V.I. Ochkur, Astrophysics 45(1), 32 (2002).
  44. S.R. Cranmer, G.B. Field, and J.L. Kohl, 518(2), 937 (1999).
  45. I.I. Antokhin, A.M. Cherepashehuk, E.A. Antokhina, and A.M. Tatarnikov, 926(2), id. 123 (2022).
  46. F. Fortin, A. Kalsi, F. Garcia, A. Simaz-Bunzel, and S. Chaty, Astron. and Astrophys. 684, id. A124 (2024).
  47. D. Folini and R. Walder, Astrophys. Space Sci. 274(1/2), 189 (2000).
  48. T.I. Madura, T.R. Gull, A.T. Okazaki, C.M.P. Russell, et al., Monthly Not. Roy. Astron. Soc. 43694, 3820 (2013).
  49. M. Mitsumoto, B. Jahanara, T. Matsuda, K. Oka, et al., Astron. Rep. 49(11), 884 (2005).
  50. M.I. Saladino, O.R. Pols, and C. Abate, Astron. and Astrophys. 626, id. A68 (2019).
  51. A.J. Gawryszczak, J. Mikolajewska, M. Razyczka, in Symbiotic Stars Probing Stellar Evolution, ASP Conference Proc., held 27–31 May 2002 at Isaac Newton Group of Telescopes, La Palma, Spain; edited by R.L.M. Corradi, R. Mikolajewska and T.J. Mahoney (San Francisco: ASP, 2003), Astron. Soc. Pacific Conf. Ser. 303, 418 (2003).
  52. A.M. Cherepashuk, T.S. Khruzina, and A.B. Bogomazov, Astron. Rep. 66(4), 348 (2022).
  53. S. Campana and T. Di Salvo, in The Physics and Astrophysics of Neutron Stars (Springer Nature Switzerland AG), Astrophys. Space Sci. Library 457, 149 (2018).
  54. A.F. Xuaxun, A.B. Cobaree, J.A. B. Bucukazo, M.M. Iaddeee, Acтpon. журн. 96(9), 748 (2019).
  55. D.S. Balsara, Suppl. 116(1), 119 (1998).
  56. A.V. Tutukov and A.V. Fedorova, Astron. Rep. 60(1), 116 (2016).
  57. A. Brahic, in The Stability of the Solar System and of Small Stellar Systems, Proc. of the Symposium, Warsaw, Poland, September 5–8, 1973; edited by Y. Kozai (Dordrecht D. Reidel Publishing Co.), IAU Symp. 62, 83 (1974).
  58. T.K. Chatterjee, Astrophys. Space Sci. 76(2), 491 (1981).
  59. S.I. Ipatov and J. Henrard, Solar System Res. 34(1), 61 (2000).
  60. V. Bosch-Ramon, M.V. Barkov, and M. Perucho, Astron. and Astrophys. 577, id. A89 (2015).
  61. P.K. Tripathi, I. Chattopadhyay, and R.K. Joshi, arXiv:2412.04815 [astro-ph.HE] (2024).
  62. L. Abalo, P. Kretschmar, F. Furst, C.M. Diez, et al., arXiv:2410.21456 [astro-ph.HE] (2024).
  63. Y-M. Lee, H. Kim, and H-W. Lee, 931(2), id. 142 (2022).
  64. J. Malfait, L. Siess, M. Esseldeurs, F. De Ceuster, S.H.J. Wallstrom, A. de Koter, and L. Decin, Astron. and Astrophys. 691, id. 84, (2024).
  65. R. Tomaru, Ch. Done, and H. Odaka, Monthly Not. Roy. Astron. Soc. 527(3), 7047 (2024).
  66. L.M. Jordan, D. Wehner, and R. Kuiper, Astron. and Astrophys. 689, id. 354 (2024).

Supplementary files

Supplementary Files
Action
1. JATS XML
Download

Copyright (c) 2025 Russian Academy of Sciences