A. Borkar scite author profile

We present a statistical analysis of polarized near-infrared (NIR) light from Sgr A*, the radio source associated with the supermassive black hole at the center of the Milky Way. The observations have been carried out using the adaptive optics instrument NACO at the VLT UT4 in the infrared Ks-band from 2004 to 2012. Several polarized flux excursions were observed during these years. Linear polarization at 2.2 µm, its statistics and time variation, can be used constrain the physical conditions of the accretion process onto this supermassive black hole. With an exponent of about 4 for the number density histogram of fluxes above 5 mJy, the distribution of polarized flux density is closely linked to the single state power-law distribution of the total Ks-band flux densities reported earlier. We find typical polarization degrees of the order of 20%±10% and a preferred polarization angle of 13 o ±15 o . Simulations show the uncertainties under a total flux density of ∼ 2 mJy are probably dominated by observational effects. At higher flux densities there are intrinsic variations of polarization degree and angle within rather well constrained ranges. Since the emission is most likely due to optically thin synchrotron radiation, this preferred polarization angle we find is very likely coupled to the intrinsic orientation of the Sgr A* system i.e. a disk or jet/wind scenario associated with the super massive black hole. If they are indeed linked to structural features of the source the data imply a rather stable geometry and accretion process for the Sgr A* system.

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Approaching hell’s kitchen: Molecular daredevil clouds in the vicinity of Sagittarius A*

Moser

Sánchez-Monge

Eckart

et al. 2017

A&A

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We report serendipitous detections of line emission with the Atacama Large Millimeter/submillimeter Array (ALMA) in bands 3, 6, and 7 in the central parsec down to within 1 around Sgr A* at an up to now highest resolution (<0.5 ) view of the Galactic center (GC) in the submillimeter (sub-mm) domain. From the 100 GHz continuum and the H39α emission we obtain a uniform electron temperature around T e ∼ 6000 K for the minispiral. The spectral index (S ∝ ν α ) of Sagittarius A* (Sgr A*) is ∼ 0.5 at 100 -250 GHz and ∼ 0.0 at 230 -340 GHz. The bright sources in the center show spectral indices around -0.1 implying Bremsstrahlung emission, while dust emission is emerging in the minispiral exterior. Apart from CS, which is most widespread in the center, H 13 CO + , HC 3 N, SiO, SO, C 2 H, CH 3 OH, 13 CS and N 2 H + are also detected. The bulk of the clumpy emission regions is at positive velocities and in a region confined by the minispiral northern arm (NA), bar, and the sources IRS 3 and 7. Although partly spatially overlapping with the radio recombination line (RRL) emission at same negative velocities, the relation to the minispiral remains unclear. A likely explanation is an infalling clump consisting of denser cloud cores embedded in diffuse gas. This central association (CA) of clouds shows three times higher CS/X (X: any other observed molecule) ratios than the circumnuclear disk (CND) suggesting a combination of higher excitation, by a temperature gradient and/or infrared (IR) pumping, and abundance enhancement due to UV and/or X-ray emission. Hence, we conclude that this CA is closer to the center than the CND is to the center. Moreover, we find molecular line emission at velocities up to 200 km s −1 . Apart from the CA, we identified two intriguing regions in the CND. One region shows emission in all molecular species and higher energy levels tested in this and previous observations and contains a methanol class I maser. The other region shows similar behavior of the line ratios such as the CA. Outside the CND, we find the traditionally quiescent gas tracer N 2 H + coinciding with the largest IR dark clouds (IRDC) in the field. Methanol emission is found at and around previously detected methanol class I masers in the same region. We propose to make these particular regions subject to further studies in the scope of hot core, cold core, and extreme photon and/or X-ray dominated region (PDR/XDR) chemistry and consequent star formation in the central few parsecs.

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A. Borkar

Monitoring the Dusty S-Cluster Object (Dso/G2) on Its Orbit Toward the Galactic Center Black Hole

The carbon footprint of large astronomy meetings

Polarized light from Sagittarius A* in the near-infraredK_s-band

Approaching hell’s kitchen: Molecular daredevil clouds in the vicinity of Sagittarius A*

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About

A. Borkar

Monitoring the Dusty S-Cluster Object (Dso/G2) on Its Orbit Toward the Galactic Center Black Hole

The carbon footprint of large astronomy meetings

Polarized light from Sagittarius A* in the near-infraredKs-band

Approaching hell’s kitchen: Molecular daredevil clouds in the vicinity of Sagittarius A*

Contact Info

Product

Resources

About

Polarized light from Sagittarius A* in the near-infraredK_s-band