Frontiers in Astronomy and Space Sciences (Nov 2017)

Multiwavelength Variability Analysis of 3C 279

  • Víctor M. Patiño-Álvarez,
  • Sunil Fernandes,
  • Vahram Chavushyan,
  • Erique López-Rodríguez,
  • Jonathan León-Tavares,
  • Eric M. Schlegel,
  • Luis Carrasco,
  • José R. Valdés,
  • Alberto Carramiñana

DOI
https://doi.org/10.3389/fspas.2017.00047
Journal volume & issue
Vol. 4

Abstract

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We present a multifrequency analysis of the variability in the flat-spectrum radio quasar 3C 279 from 2008 to 2014. Our multiwavelength datasets range from 1 mm to gamma-rays, with additional optical polarimetry. Cross-correlation analysis shows a significant correlation between the UV continuum emission, the optical and NIR bands, at a delay consistent with zero, implying co-spatial emission regions. We also find a correlation between the UV continuum and the 1 mm data, which implies that the dominant process in producing the UV continuum is synchrotron emission. Based on the behavior of the gamma-ray light curve with respect to other bands, we identified three different activity periods. During period A we find a significant correlation at zero delay between the UV continuum and the gamma-rays, implying co-spatial emission regions which points toward synchrotron self-Compton as dominant gamma-ray emission mechanism. During period C we find a delay between the UV continuum and the gamma-rays, as well as a correlation at zero delay between X-rays and gamma-rays, both results implying that external inverse Compton is the dominant gamma-ray emission mechanism. During period B there are multiple flares in the bands from 1 mm to UV, however, none of these show a counterpart in the gamma-rays band. We propose that this is caused by an increase in the gamma-ray opacity due to electron-positron pair production.

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