Evidence for dust clearing through resolved submillimeter imaging

TL;DR

This study directly images and characterizes large inner gaps in protoplanetary disks, confirming that dust clearing creates observable holes, supporting SED-based models and advancing understanding of disk evolution.

Contribution

First direct imaging of resolved inner gaps in three protoplanetary disks, validating SED-based inferences and highlighting potential planetary influences.

Findings

Large inner gaps (33-47 AU) are fully resolved and mostly dust-free.

Gas remains present inside the dust-depleted regions.

Inner gaps likely caused by gravitational influence of companions.

Abstract

Mid-infrared spectrophotometric observations have revealed a small sub-class of circumstellar disks with spectral energy distributions (SEDs) suggestive of large inner gaps with low dust content. However, such data provide only an indirect and model-dependent method of finding central holes. Imaging of protoplanetry disks provides an independent check of SED modeling. We present here the direct characterization of three 33-47 AU radii inner gaps, in the disks around LkHa 330, SR 21N and HD 135344B, via 340 GHz (880 micron) dust continuum aperture synthesis observations obtained with the Submillimeter Array (SMA). The large gaps are fully resolved at ~0\farcs3 by the SMA observations and mostly empty of dust, with less than 1 - 7.5 x 10^-6 Msolar of fine grained solids inside the holes. Gas (as traced by atomic accretion markers and CO 4.7 micron rovibrational emission) is still present in the inner regions of all three disks. For each, the inner hole exhibits a relatively steep rise in dust emission to the outer disk, a feature more likely to originate from the gravitational influence of a companion body than from a process expected to show a more shallow gradient like grain growth. Importantly, the good agreement of the spatially resolved data and spectrophotometry-based models lends confidence to current interpretations of SEDs, wherein the significant dust emission deficits arise from disks with inner gaps or holes. Further SED-based searches can therefore be expected to yield numerous additional candidates that can be examined at high spatial resolution.