Polarized NIR and X-ray Flares from SgrA*

TL;DR

This study investigates the polarized near-infrared and X-ray flares from SgrA*, revealing their synchronous nature, non-thermal origin, and potential explanations involving a temporary disk and jet structure around the SMBH.

Contribution

It provides new observational evidence of synchronous NIR/X-ray flares from SgrA* and interprets these in terms of a disk-jet model with relativistic spots.

Findings

Synchronous NIR and X-ray flares with no time lag less than 10 minutes.

Flares are non-thermal and polarized, consistent with synchrotron self-Compton processes.

Variations in flare profiles suggest dynamic spot structures in a relativistic disk.

Abstract

Stellar dynamics indicate the presence of a super massive 3-4x10^6 Msun solm black hole at the Galactic Center. It is associated with the variable radio, near-infrared, and X-ray counterpart Sagittarius A* (SgrA*). The goal is the investigation and understanding of the physical processes responsible for the variable emission from SgrA*. The observations have been carried out using the NACO adaptive optics (AO) instrument at the European Southern Observatory's Very Large Telescope (July 2005, May 2007) and the ACIS-I instrument aboard the Chandra X-ray Observatory (July 2005). We find that for the July 2005 flare the variable and polarized NIR emission of SgrA* occurred synchronous with a moderately bright flare event in the X-ray domain with an excess 2 - 8 keV luminosity of about 8x10^33erg/s. We find no time lag between the flare events in the two wavelength bands with a lower limit of less than 10 minutes. The May 2007 flare shows the highest sub-flare to flare contrast observed until now. It provides evidence for a variation in the profile of consecutive sub-flares. We confirm that highly variable and NIR polarized flare emission is non-thermal and that there exists a class of synchronous NIR/X-ray flares. We find that the flaring state can be explained via the synchrotron self-Compton (SSC) process involving up-scattered sub-millimeter photons from a compact source component. The observations can be interpreted in a model involving a temporary disk with a short jet. In the disk component the flux density variations can be explained due to spots on relativistic orbits around the central super massive black hole (SMBH). The profile variations for the May 2007 flare are interpreted as a variation of the spot structure due to differential rotation within the disk.