# Nature of the Galactic centre NIR-excess sources. I. What can we learn   from the continuum observations of the DSO/G2 source?

**Authors:** Michal Zaja\v{c}ek, Silke Britzen, Andreas Eckart, Banafsheh, Shahzamanian, Gerold Busch, Vladim\'ir Karas, Marzieh Parsa, Florian, Peissker, Michal Dov\v{c}iak, Matthias Subroweit, Franti\v{s}ek Dinnbier,, Anton Zensus

arXiv: 1704.03699 · 2017-06-28

## TL;DR

This study uses continuum and polarimetry observations, combined with radiative transfer modeling, to investigate the nature of the DSO/G2 source near the Galactic center, suggesting it is likely a young stellar object or a neutron star with a complex environment.

## Contribution

The paper presents a comprehensive 3D radiative transfer model of the DSO/G2, constraining its nature as a young stellar object or neutron star with detailed envelope and bow shock structures.

## Key findings

- DSO/G2 is a compact source within 0.04 pc of Sgr A*.
- It is likely a young stellar object embedded in a dusty envelope.
- Alternatively, it could be a non-thermal source like a neutron star wind nebula.

## Abstract

The Dusty S-cluster Object (DSO/G2) orbiting the supermassive black hole (Sgr A*) in the Galactic centre has been monitored in both near-infrared continuum and line emission. There has been a dispute about the character and the compactness of the object: interpreting it as either a gas cloud or a dust-enshrouded star. A recent analysis of polarimetry data in $K_{\rm s}$-band ($2.2\,{\rm \mu m}$) allows us to put further constraints on the geometry of the DSO. The purpose of this paper is to constrain the nature and the geometry of the DSO. We compare 3D radiative transfer models of the DSO with the NIR continuum data including polarimetry. In the analysis, we use basic dust continuum radiative transfer theory implemented in the 3D Monte Carlo code Hyperion. Moreover, we implement analytical results of the two-body problem mechanics and the theory of non-thermal processes. We present a composite model of the DSO -- a dust-enshrouded star that consists of a stellar source, dusty, optically thick envelope, bipolar cavities, and a bow shock. This scheme can match the NIR total as well as polarized properties of the observed spectral energy distribution (SED). The SED may be also explained in theory by a young pulsar wind nebula that typically exhibits a large linear polarization degree due to magnetospheric synchrotron emission. The analysis of NIR polarimetry data combined with the radiative transfer modelling shows that the DSO is a peculiar source of compact nature in the S cluster $(r \lesssim 0.04\,{\rm pc})$. It is most probably a young stellar object embedded in a non-spherical dusty envelope, whose components include optically thick dusty envelope, bipolar cavities, and a bow shock. Alternatively, the continuum emission could be of a non-thermal origin due to the presence of a young neutron star and its wind nebula.

## Full text

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## Figures

19 figures with captions in the complete paper: https://tomesphere.com/paper/1704.03699/full.md

## References

102 references — full list in the complete paper: https://tomesphere.com/paper/1704.03699/full.md

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Source: https://tomesphere.com/paper/1704.03699