Salt, Hot Water, and Silicon Compounds Tracing Massive Twin Disks

Tanaka, Kei E. I. and Zhang, Yichen and Hirota, Tomoya and Sakai, Nami and Motogi, Kazuhito and Tomida, Kengo and Tan, Jonathan C. and Rosero, Viviana and Higuchi, Aya E. and Ohashi, Satoshi and Liu, Mengyao and Sugiyama, Koichiro (2020) Salt, Hot Water, and Silicon Compounds Tracing Massive Twin Disks. The Astrophysical Journal Letters, 900 (1). L2. ISSN 2041-8205

[thumbnail of Tanaka_2020_ApJL_900_L2.pdf] Text
Tanaka_2020_ApJL_900_L2.pdf - Published Version

Download (2MB)

Abstract

We report results of $0\buildrel{\prime\prime}\over{.} 05$-resolution observations toward the O-type proto-binary system IRAS 16547–4247 with the Atacama Large Millimeter/submillimeter Array. We present dynamical and chemical structures of the circumbinary disk, circumstellar disks, outflows, and jets, illustrated by multi-wavelength continuum and various molecular lines. In particular, we detect sodium chloride, silicon compounds, and vibrationally excited water lines as probes of the individual protostellar disks at a scale of 100 au. These are complementary to typical hot-core molecules tracing the circumbinary structures on a 1000 au scale. The H2O line tracing inner disks has an upper-state energy of ${E}_{u}/k\gt 3000\,{\rm{K}}$, indicating a high temperature of the disks. On the other hand, despite the detected transitions of NaCl, SiO, and SiS not necessarily having high upper-state energies, they are enhanced only in the vicinity of the protostars. We posit that these molecules are the products of dust destruction, which only happens in the inner disks. This is the second detection of alkali metal halide in protostellar systems after the case of the disk of Orion Source I, and also one of few massive protostellar disks associated with high-energy transition water and silicon compounds. These new results suggest that these "hot-disk" lines may be common in innermost disks around massive protostars, and have great potential for future research of massive star formation. We also tentatively find that the twin disks are counter-rotating, which might give a hint of the origin of the massive proto-binary system IRAS 16547–4247.

Item Type: Article
Subjects: Archive Science > Physics and Astronomy
Depositing User: Managing Editor
Date Deposited: 23 May 2023 07:19
Last Modified: 07 Jun 2024 10:58
URI: http://editor.pacificarchive.com/id/eprint/945

Actions (login required)

View Item
View Item