An asymmetric dust ring around a very low mass star ZZ Tau IRS

We present Atacama Large Millimeter/submillimeter Array (ALMA) gas and dust observations at band 7 (339~GHz: 0.89~mm) of the protoplanetary disk around a very low mass star ZZ~Tau~IRS with a spatial resolution of 0\farcs25. The \(^{12}\)CO~\(J=3\rightarrow2\) position--velocity diagram suggests a dy...

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Bibliographic Details
Published in:arXiv.org 2021-03
Main Authors: Hashimoto, Jun, Dong, Ruobing, Muto, Takayuki
Format: Article
Language:English
Subjects:
Aspect ratio
Asymmetry
Deposition
Dust
Flux density
Low mass stars
Planet formation
Protoplanetary disks
Radio telescopes
Spatial resolution
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Summary:We present Atacama Large Millimeter/submillimeter Array (ALMA) gas and dust observations at band 7 (339~GHz: 0.89~mm) of the protoplanetary disk around a very low mass star ZZ~Tau~IRS with a spatial resolution of 0\farcs25. The \(^{12}\)CO~\(J=3\rightarrow2\) position--velocity diagram suggests a dynamical mass of ZZ~Tau~IRS of \(\sim\)0.1--0.3~\(M_{\sun}\). The disk has a total flux density of 273.9 mJy, corresponding to an estimated mass of 24--50~\(M_\oplus\) in dust. The dust emission map shows a ring at \(r=\) 58~au and an azimuthal asymmetry at \(r=\) \jh{45}~au with a position angle of 135\degr. The properties of the asymmetry, including radial width, aspect ratio, contrast, and contribution to the total flux, were found to be similar to the asymmetries around intermediate mass stars (\(\sim\)2~\(M_{\sun}\)) such as MWC~758 and IRS~48. This implies that the asymmetry in the ZZ~Tau~IRS disk shares a similar origin with others, despite the star being \(\sim\)10 times less massive. Our observations also suggest that the inner and outer parts of the disk may be misaligned. Overall, the ZZ~Tau~IRS disk shows evidence of giant planet formation at \(\sim\)10 au scale at a few Myr. If confirmed, it will challenge existing core accretion models, in which such planets have been predicted to be extremely hard to form around very low mass stars.
ISSN:2331-8422
DOI:10.48550/arxiv.2103.16731