Planet formation and dynamics

The signature of orbital motion from the dayside of the planet tau Bootis b

(2012)

Authors:

M Brogi, IAG Snellen, RJ de Kok, S Albrecht, J Birkby, EJW de Mooij

Discovery and characterisation of detached M-dwarf eclipsing binaries in the WFCAM Transit Survey

(2012)

Authors:

JL Birkby, SV Nefs, ST Hodgkin, G Kovács, B Sipöcz, DJ Pinfield, IAG Snellen, D Mislis, F Murgas, N Lodieu, EJW de Mooij, N Goulding, P Cruz, H Stoev, M Cappetta, E Pallé, D Barrado, R Saglia, EL Martín, Y Pavlenko

Four ultra-short period eclipsing M-dwarf binaries in the WFCAM Transit Survey

(2012)

Authors:

SV Nefs, JL Birkby, IAG Snellen, ST Hodgkin, DJ Pinfield, B Sipocz, G Kovacs, D Mislis, RP Saglia, J Koppenhofer, P Cruz, D Barrado, EL Martin, N Goulding, H Stoev, J Zendejas, C del Burgo, M Cappetta, YV Pavlenko

The signature of orbital motion from the dayside of the planet τ Boötis b.

Nature 486:7404 (2012) 502-504

Authors:

Matteo Brogi, Ignas AG Snellen, Remco J de Kok, Simon Albrecht, Jayne Birkby, Ernst JW de Mooij

Abstract:

The giant planet orbiting τ Boötis (named τ Boötis b) was amongst the first extrasolar planets to be discovered. It is one of the brightest exoplanets and one of the nearest to us, with an orbital period of just a few days. Over the course of more than a decade, measurements of its orbital inclination have been announced and refuted, and have hitherto remained elusive. Here we report the detection of carbon monoxide absorption in the thermal dayside spectrum of τ Boötis b. At a spectral resolution of ∼100,000, we trace the change in the radial velocity of the planet over a large range in phase, determining an orbital inclination of 44.5° ± 1.5° and a mass 5.95 ± 0.28 times that of Jupiter, demonstrating that atmospheric characterization is possible for non-transiting planets. The strong absorption signal points to an atmosphere with a temperature that is decreasing towards higher altitudes, in contrast to the temperature inversion inferred for other highly irradiated planets. This supports the hypothesis that the absorbing compounds believed to cause such atmospheric inversions are destroyed in τ Boötis b by the ultraviolet emission from the active host star.

Protoplanets with core masses below the critical mass fill in their Roche lobe

Monthly Notices of the Royal Astronomical Society 418:3 (2011) 1928-1934

Authors:

C Terquem, T Heinemann

Abstract:

We study the evolution of a protoplanet of a few earth masses embedded in a protoplanetary disc. If we assume that the atmosphere of the protoplanet, i.e. the volume of gas in hydrostatic equilibrium bound to the core, has a surface radius smaller than the Roche lobe radius, we show that it expands as it accretes both planetesimals and gas at a fixed rate from the nebula until it fills in the Roche lobe. The evolution occurs on a time-scale shorter than the formation or migration time-scales. Therefore, we conclude that protoplanets of a few earth masses have an atmosphere that extends to the Roche lobe surface, where it joins on to the nebula. This is true even when the Bondi radius is smaller than the Roche lobe radius. This is in contrast to the commonly used models in which the static atmosphere extends up to the Bondi radius and is surrounded by a cold accretion flow. As a result, any calculation of the tidal torque exerted by the disc on to the protoplanet should exclude the material present in the Roche lobe, since it is bound to the protoplanet. © 2011 The Authors Monthly Notices of the Royal Astronomical Society © 2011 RAS.