HD 169142 - Interacting planets forming in a disk?

An Enigmatic Pointlike Feature within the HD 169142 Transitional Disk
http://arxiv.org/abs/1408.0794

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We report the detection of a faint pointlike feature possibly related to ongoing planet-formation in the disk of the transition disk star HD 169142. The pointlike feature has a Δ mag(L)∼ 6.4, at a separation of ∼ 0.11" and PA∼ 0 ∘ . Given its lack of an H or K S counterpart despite its relative brightness, this candidate cannot be explained by purely photospheric emission and must be a disk feature heated by an as yet unknown source. Its extremely red colors make it highly unlikely to be a background object, but future multi-wavelength followup is necessary for confirmation and characterization of this feature.

Discovery of a Companion Candidate in the HD169142 Transition Disk and the Possibility of Multiple Planet Formation
http://arxiv.org/abs/1408.0813

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We present L' and J-band high-contrast observations of HD169142, obtained with the VLT/NACO AGPM vector vortex coronagraph and the Gemini Planet Imager, respectively. A source located at 0".156+/-0".032 north of the host star (PA=7.4+/-11.3 degrees) appears in the final reduced L' image. At the distance of the star (~145 pc), this angular separation corresponds to a physical separation of 22.7+/-4.7 AU, locating the source within the recently resolved inner cavity of the transition disk. The source has a brightness of L'=12.2+/-0.5 mag, whereas it is not detected in the J band (J>13.8 mag). If its L' brightness arose solely from the photosphere of a companion and given the J-L' color constraints, it would correspond to a 28-32 MJupiter object at the age of the star, according to the COND models. Ongoing accretion activity of the star suggests, however, that gas is left in the inner disk cavity from which the companion could also be accreting. In this case the object could be lower in mass and its luminosity enhanced by the accretion process and by a circumplanetary disk. A lower mass object is more consistent with the observed cavity width. Finally, the observations enable us to place an upper limit on the L'-band flux of a second companion candidate orbiting in the disk annular gap at ~50 AU, as suggested by millimeter observations. If the second companion is also confirmed, HD169142 might be forming a planetary system, with at least two companions opening gaps and possibly interacting with each other.

Is this the same object?

Both papers are primarily about the same object, yes.

Since it's highly relevant:

Variability of Disk Emission in Pre-Main Sequence and Related Stars. III. Exploring Structural Changes in the Pre-transitional Disk in HD 169142

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We present near-IR and far-UV observations of the pre-transitional (gapped) disk in HD 169142 using NASA's Infrared Telescope Facility and Hubble Space Telescope. The combination of our data along with existing data sets into the broadband spectral energy distribution reveals variability of up to 45% between ~1.5-10 μm over a maximum timescale of 10 years. All observations known to us separate into two distinct states corresponding to a high near-IR state in the pre-2000 epoch and a low state in the post-2000 epoch, indicating activity within the <1 AU region of the disk. Through analysis of the Pa β and Br γ lines in our data we derive a mass accretion rate in May 2013 of (1.5 - 2.7) x 10^-9 Msun/yr. We present a theoretical modeling analysis of the disk in HD 169142 using Monte-Carlo radiative transfer simulation software to explore the conditions and perhaps signs of planetary formation in our collection of 24 years of observations. We find that shifting the outer edge (r = 0.3 AU) of the inner disk by 0.05 AU toward the star (in simulation of accretion and/or sculpting by forming planets) successfully reproduces the shift in NIR flux. We establish that the ~40-70 AU dark ring imaged in the NIR by Quanz et al. (2013) and Momose et al. (2013) and at 7 mm by Osorio et al. (2014) may be reproduced with a 30% scaled density profile throughout the region, strengthening the link to this structure being dynamically cleared by one or more planetary mass bodies.

This paper is an extensive study of this system's disks, of which the innermost has shown significant changes in character on the timescale of a few decades.

The outer system has been characterised as an extensive disk with a cavity within 25 AU and a peculiar gap between 40 and 70 AU which is here identified as a region of decreased density. The inner gap is consistent with the position of the previously identified planet candidate (~20 AU), while the outer gap contains (at ~50 AU) a bright feature which was identified as a possible protoplanet in its discovery paper (Osorio et al. (2014)). While the changes in the inner disk are consistent with actions related to accretion by the star, There is nevertheless a large region (0.3 - 20 AU) that is cleared of material which has not yet been studied.

https://arxiv.org/abs/1702.02844

ALMA unveils rings and gaps in the protoplanetary system HD 169142: signatures of two giant protoplanets

https://arxiv.org/abs/1709.01734

Investigation of the inner structures around HD169142 with VLT/SPHERE

We present observations of the Herbig Ae star HD169142 with VLT/SPHERE instruments IRDIS (K1K2 and H2H3 bands) and IFS (Y-, J- and H-bands). We detect several bright blobs at ~180 mas separation from the star, and a faint arc-like structure in the IFS data. Our Radial Differential Imaging data analysis also displays a bright ring at the same separation. We show, using a simulation based on polarized light data, that these blobs are actually part of the ring at 180 mas. These results demonstrate that the earlier detections of blobs in H- and K s -bands at these separations in Biller et al. (2014) as potential planet/substellar companions are actually tracing a bright ring with a Keplerian motion. Moreover, we detect in the images an additional bright structure at ~93 mas separation and PA=355{\deg}, at a location very close to previous detections. It appears point-like in the YJ- and K-bands but is more extended in the H-band. We also marginally detect an inner ring in the RDI data at ~100 mas. Follow-up observations are necessary to confirm the detection and the nature of this source and structure.

Another update:

Gratton et al. "Blobs, spiral arms, and a possible planet around HD 169142"
https://arxiv.org/abs/1901.06555

Possible 1–4 M_J planet at ~38 AU still undergoing accretion.

Dust unveils the formation of a mini-Neptune planet in a protoplanetary ring
https://arxiv.org/abs/1902.05143

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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⊕), 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.