TY - JOUR
T1 - A likely planet-induced gap in the disc around T Cha
AU - Hendler, Nathanial P.
AU - Pinilla, Paola
AU - Pascucci, Ilaria
AU - Pohl, Adriana
AU - Mulders, Gijs
AU - Henning, Thomas
AU - Dong, Ruobing
AU - Clarke, Cathie
AU - Owen, James
AU - Hollenbach, David
N1 - Publisher Copyright:
© 2017 The Author(s) Published by Oxford University Press on behalf of the Royal Astronomical Society
PY - 2018/3/1
Y1 - 2018/3/1
N2 - We present high-resolution (0.11 × 0.06 arcsec2) 3 mm ALMA observations of the highly inclined transition disc around the star T Cha. Our continuum image reveals multiple dust structures: an inner disc, a spatially resolved dust gap, and an outer ring. When fitting sky-brightness models to the real component of the 3 mm visibilities, we infer that the inner emission is compact (≤1 au in radius), the gap width is between 18 and 28 au, and the emission from the outer ring peaks at ∼36 au. We compare our ALMA image with previously published 1.6 µm VLT/SPHERE imagery. This comparison reveals that the location of the outer ring is wavelength dependent. More specifically, the peak emission of the 3 mm ring is at a larger radial distance than that of the 1.6 µm ring, suggesting that millimeter-sized grains in the outer disc are located farther away from the central star than micron-sized grains. We discuss different scenarios to explain our findings, including dead zones, star-driven photoevaporation, and planet-disc interactions. We find that the most likely origin of the dust gap is from an embedded planet, and estimate - for a single planet scenario - that T Cha's gap is carved by a 1.2MJup planet.
AB - We present high-resolution (0.11 × 0.06 arcsec2) 3 mm ALMA observations of the highly inclined transition disc around the star T Cha. Our continuum image reveals multiple dust structures: an inner disc, a spatially resolved dust gap, and an outer ring. When fitting sky-brightness models to the real component of the 3 mm visibilities, we infer that the inner emission is compact (≤1 au in radius), the gap width is between 18 and 28 au, and the emission from the outer ring peaks at ∼36 au. We compare our ALMA image with previously published 1.6 µm VLT/SPHERE imagery. This comparison reveals that the location of the outer ring is wavelength dependent. More specifically, the peak emission of the 3 mm ring is at a larger radial distance than that of the 1.6 µm ring, suggesting that millimeter-sized grains in the outer disc are located farther away from the central star than micron-sized grains. We discuss different scenarios to explain our findings, including dead zones, star-driven photoevaporation, and planet-disc interactions. We find that the most likely origin of the dust gap is from an embedded planet, and estimate - for a single planet scenario - that T Cha's gap is carved by a 1.2MJup planet.
KW - Circumstellar matter
KW - Planet-disc interactions
KW - Planets and satellites: detection
KW - Planets and satellites: formation
KW - Protoplanetary discs
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U2 - 10.1093/mnrasl/slx184
DO - 10.1093/mnrasl/slx184
M3 - Article
AN - SCOPUS:85102949162
SN - 1745-3925
VL - 475
SP - L62-L66
JO - Monthly Notices of the Royal Astronomical Society: Letters
JF - Monthly Notices of the Royal Astronomical Society: Letters
IS - 1
ER -