Abstract
The unusual spectral energy distribution (SED) of the classical T Tauri star GM Aurigae provides evidence for the presence of an inner disc hole extending to several au. Using a combination of hydrodynamical simulations and Monte Carlo radiative transport, we investigate whether the observed SED is consistent with the inner hole being created and maintained by an orbiting planet. We show that an similar to2 MJ planet, orbiting at 2.5 au in a disc with mass 0.047 M-. and radius 300 au, provides a good match both to the SED and to CO observations which constrain the velocity field in the disc. A range of planet masses is allowed by current data, but could in principle be distinguished with further observations between 3 and similar to20 mum. Future high-precision astrometric instruments should also be able to detect the motion of the central star caused by an orbiting Jupiter-mass planet. We argue that the small number of T Tauri stars with SEDs resembling that of GM Aur is broadly consistent with the expected statistics of embedded migrating planets.
Original language | English |
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Pages (from-to) | 79-85 |
Number of pages | 7 |
Journal | Monthly Notices of the Royal Astronomical Society |
Volume | 342 |
Issue number | 1 |
DOIs | |
Publication status | Published - 11 Jun 2003 |
Keywords
- accretion, accretion discs
- radiative transfer
- scattering
- planetary systems : protoplanetary discs
- stars : pre-main-sequence
- dust, extinction
- MAIN-SEQUENCE EVOLUTION
- T-TAURI STARS
- SPECTRAL ENERGY-DISTRIBUTIONS
- YOUNG STELLAR OBJECTS
- ACCRETION DISKS
- ORBITAL MIGRATION
- BINARY-SYSTEMS
- ASTROMETRIC SIGNATURES
- CIRCUMSTELLAR DISKS
- EXTRASOLAR PLANETS