SDSS J080434.20+510349.2 spectra and photometry Virtual Observatory Resource

Authors
  1. Zharikov S.
  2. Tovmassian G.
  3. Aviles A.
  4. Michel R.
  5. Gonzalez-Buitrago D.,Garcia-Diaz M.T.
  6. Published by
    CDS
Abstract

This study of SDSS J080434.20+510349.2 (SDSS0804) is primarily concerned with the double-hump shape in the light curve and its connection with the accretion disk in this bounce-back system. Time-resolved photometric and spectroscopic observations were obtained to analyze the behavior of the system between superoutbursts. A qualitative geometric model of a binary system containing a disk with two outer annuli spiral density waves was applied to explain the light curve and the Doppler tomography. Observations were carried out during 2008-2009, after the object's magnitude decreased to V~17.7+/-0.1 from the March 2006 eruption. The light curve clearly shows a sinusoid-like variability with a 0.07mag amplitude and a 42.48min periodicity, which is half of the orbital period of the system. In September 2010, the system underwent yet another superoutburst and returned to its quiescent level by the beginning of 2012. This light curve once again showed a double-hump-shape, but with a significantly smaller (~0.01mag) amplitude. Other types of variability like a "mini-outburst" or SDSS1238-like features were not detected. Doppler tomograms, obtained from spectroscopic data during the same period of time, show a large accretion disk with uneven brightness, implying the presence of spiral waves. We constructed a geometric model of a bounce-back system containing two spiral density waves in the outer annuli of the disk to reproduce the observed light curves. The Doppler tomograms and the double-hump-shape light curves in quiescence can be explained by a model system containing a massive >=0.7M_{sun}_ white dwarf with a surface temperature of ~12000K, a late-type brown dwarf, and an accretion disk with two outer annuli spirals. According to this model, the accretion disk should be large, extending to the 2:1 resonance radius, and cool ~2500K. The inner parts of the disk should be optically thin in the continuum or totally void.

Keywords
  1. cataclysmic-variable-stars
  2. photometry
  3. spectroscopy
Bibliographic source Bibcode
2013A&A...549A..77Z
See also HTML
https://cdsarc.cds.unistra.fr/viz-bin/cat/J/A+A/549/A77
IVOA Identifier IVOID
ivo://CDS.VizieR/J/A+A/549/A77
Document Object Identifer DOI
doi:10.26093/cds/vizier.35490077

Access

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http://vizieridia.saao.ac.za/viz-bin/VizieR-2?-source=J/A+A/549/A77
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History

2012-12-21T08:53:41Z
Resource record created
2012-12-21T08:53:41Z
Created
2017-06-01T08:51:59Z
Updated

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