http://arxiv.org/abs/1902.05143
Rings and radial gaps are ubiquitous in protoplanetary disks. Their possible connection to planet formation is currently subject to intense debate. In principle, giant planet formation leads to wide gaps which separate the gas and dust mass reservoir in the outer disk, while lower mass planets lead to shallow gaps which are manifested mainly on the dust component. We used the Atacama Large Millimeter/submillimeter Array (ALMA) to observe the star HD 169142, host to a prominent disk with deep wide gaps that sever the disk into inner and outer regions. Here we report that the outer ring of the HD 169142 disk is itself a compact system of three fine and eccentric rings. The mass reservoir beyond a deep gap can thus host ring systems. The observed rings are narrow in radial extent (width/radius of 1.5/57.3, 1.8/64.2 and 3.4/76.0, all in au) and have asymmetric mutual separations: the first and middle ring are separated by 7 au while the middle and outermost ring are distanced by 12 au. Using hydrodynamical modeling we found that a simple explanation, involving a single migrating low mass planet (10 M$_\oplus$), entirely counts for such an apparently complex phenomenon. Inward migration of the planet naturally explains the ring’s asymmetric mutual separation. The isolation of HD 169142’s outer rings thus allows a proof of concept to interpret the detailed architecture of the outer region of protoplanetary disks with low mass planet formation of mini-Neptune’s size, i.e. as in the protosolar nebula.
S. Pérez, S. Casassus, C. Baruteau, et. al.
Fri, 15 Feb 19
5/48
Comments: 13 pages. 4 figures in the main text plus 4 in appendices. Paper submitted
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