Multiband optical variability of blazar Ton 599 Virtual Observatory Resource

Authors
  1. Vince O.
  2. Raiteri C.M.
  3. Villata M.
  4. Gupta A.C.
  5. Kovacevic-Dojcinovic J.,Lakicevic M.
  6. Popovic L.C.
  7. Kushwaha P.
  8. Mirzaqulov D.O.
  9. Ehgamberdiev S.A.,Carosati D.
  10. Jorstad S.G.
  11. Marscher A.P.
  12. Weaver Z.R.
  13. Webb J.R.,Smith P.S.
  14. Chen W.
  15. Tsai A.
  16. Lin H.
  17. Borman G.A.
  18. Grishina T.S.,Hagen-Thorn V.A.
  19. Kopatskaya E.N.
  20. Larionova E.G.
  21. Larionov V.M.,Larionova L.V.
  22. Morozova D.A.
  23. Savchenko S.
  24. Troitskiy I.S.,Troitskaya Y.V.
  25. Vasilyev A.
  26. Zhovtan A.V.
  27. Shishkina E.V.
  28. Kurtanidze O.M.,Nikolashvili M.G.
  29. Kurtanidze S.O.
  30. Ivanidze R.
  31. Acosta-Pulido J.A.,Carnerero M.I.
  32. Damljanovic G.
  33. Stojanovic M.
  34. Jovanovic M.D.
  35. Vlasyuk V.,Spiridonova O.I.
  36. Moskvitin A.S.
  37. Pursimo T.
  38. Elsasser D.
  39. Feige M.,Kunkel L.
  40. Ledermann J.
  41. Reinhart D.
  42. Scherbantin A.
  43. Schoch K.,Steineke R.
  44. Lorey C.
  45. Agudo I.
  46. Escudero Pedrosa J.
  47. Aceituno F.J.,Bonnoli G.
  48. Casanova V.
  49. Morcuende D.
  50. Sota A.
  51. Bozhilov V.
  52. Valcheva A.,Zaharieva E.
  53. Minev M.
  54. Strigachev A.
  55. Bachev R.
  56. Mihov B.,Slavcheva-Mihova L.
  57. Sadun A.C.
  58. Takey A.
  59. Shokry A.
  60. El-Sadek M.A.,Marchini A.
  61. Verna G.
    62. Published by
    CDS
Abstract

We analyze the optical variability of the flat-spectrum radio quasar (FSRQ) Ton 599 using BVRI photometry from the WEBT Collaboration (2011-2023), complemented by Steward Observatory monitoring. The study characterizes flux distributions, intranight changes, color evolution, and spectra to constrain physical parameters and processes in the central engine. We test flux distributions against normal and log-normal models, derive power spectral densities (PSDs), quantify intranight variability, and estimate emitting region sizes and magnetic fields from variability timescales. Long-term behavior is investigated by segmenting the light curves into 12 intervals, and color evolution is traced through color-magnitude and color-time diagrams. MgII line properties from low-flux spectra provide a black hole mass estimate. Ton 599 shows strong optical variability with log-normal flux distributions, red-noise PSDs, positive rms-flux relations, intranight variability, and a redder-when-brighter to bluer-when-brighter evolution depending on flux state. The peak R-band flux reaches 23.5mJy (log{nu}L{nu}=48.48[erg/s]). The estimated black hole mass is of order 10^8^M_{sun}_, consistent with previous studies.

Keywords
  1. quasars
  2. photometry
  3. visible-astronomy
Bibliographic source Bibcode
2025A&A...703A.259V
See also HTML
https://cdsarc.cds.unistra.fr/viz-bin/cat/J/A+A/703/A259
IVOA Identifier IVOID
ivo://CDS.VizieR/J/A+A/703/A259

Access

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http://vizieridia.saao.ac.za/viz-bin/VizieR-2?-source=J/A+A/703/A259
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History

2025-12-01T09:50:36Z
Resource record created
2025-12-01T08:54:15Z
Updated
2025-12-01T09:50:36Z
Created

Contact

Name
CDS support team
Postal Address
CDS, Observatoire de Strasbourg, 11 rue de l'Universite, F-67000 Strasbourg, France
E-Mail
cds-question@unistra.fr