The disk-outflow system in the S255IR area of high mass star formation

I. Zinchenko (1; 2); S.-Y. Liu (3); Y.-N. Su (3); S. V. Salii (4),; A. M. Sobolev (4); P. Zemlyanukha (1; 2); H. Beuther (5); D. K. Ojha (6),; M. R. Samal (7); Y. Wang (8; 9) ((1) Institute of Applied Physics of the; Russian Academy of Sciences; Nizhny Novgorod; Russia; (2) Lobachevsky State; University of Nizhni Novgorod; Russia; (3) Institute of Astronomy and; Astrophysics; Academia Sinica; Taipei; Taiwan; R.O.C.; (4) Ural Federal; University; Ekaterinburg; Russia; (5) Max-Planck-Institut f\"ur Astronomie,; Heidelberg; Germany; (6) Infrared Astronomy Group; Department of Astronomy; and Astrophysics; Tata Institute of Fundamental Research; Mumbai (Bombay),; India; (7) Laboratoire d'Astrophysique de Marseille; France; (8) Department; of Astronomy; University of Geneva; Switzerland; (9) Purple Mountain; Observatory; CAS; China)

arXiv:1507.05642·astro-ph.GA·September 9, 2015

The disk-outflow system in the S255IR area of high mass star formation

I. Zinchenko (1, 2), S.-Y. Liu (3), Y.-N. Su (3), S. V. Salii (4),, A. M. Sobolev (4), P. Zemlyanukha (1, 2), H. Beuther (5), D. K. Ojha (6),, M. R. Samal (7), Y. Wang (8, 9) ((1) Institute of Applied Physics of the, Russian Academy of Sciences, Nizhny Novgorod, Russia

PDF

TL;DR

This study presents high-resolution observations of the S255IR high-mass star-forming region, revealing a rotating disk, complex outflow structures, and chemical variations influenced by energetic processes.

Contribution

It provides detailed imaging of the disk-outflow system in S255IR, highlighting fragmentation, outflow morphology, and chemical signatures, advancing understanding of massive star formation mechanisms.

Findings

01

Detection of a rotating structure around a massive young star.

02

Identification of a complex, episodic outflow driven by jet bow shocks.

03

Chemical variations indicating impact of outflows on surrounding medium.

Abstract

We report the results of our observations of the S255IR area with the SMA at 1.3 mm in the very extended configuration and at 0.8 mm in the compact configuration as well as with the IRAM-30m at 0.8 mm. The best achieved angular resolution is about 0.4 arcsec. The dust continuum emission and several tens of molecular spectral lines are observed. The majority of the lines is detected only towards the S255IR-SMA1 clump, which represents a rotating structure (probably disk) around the young massive star. The achieved angular resolution is still insufficient for conclusions about Keplerian or non-Keplerian character of the rotation. The temperature of the molecular gas reaches 130-180 K. The size of the clump is about 500 AU. The clump is strongly fragmented as follows from the low beam filling factor. The mass of the hot gas is significantly lower than the mass of the central star. A strong…

Peer Reviews

No public reviews on file for this paper yet. If you reviewed it on a platform where reviews are public (OpenReview, ICLR, NeurIPS, ICML), you can paste yours below so the community can read it here.

Videos

No videos yet. Explain this paper in a talk, walkthrough, or lecture? Add one.