Title: CO Gas orbiting around the GG Tauri A triple System: rings beyond the ring ? Author: Ya-Wen Tang (1), Anne Dutrey (2), Stephane Guilloteau (2), Edwige Chapillon (3), Vincent Pietu (3), Emmanuel Di Folco (2), Jeff Bary (4), Tracy Beck (5), Herve Beust (6), Yann Boehler (7), Frederic Gueth (3), Jean-Marc Hure (2), Arnaud Pierens (2), Michal Simon (8) ((1) Academia Sinica, Institute of Astronomy and Astrophysics (2) Universite de Bordeaux, Observatoire Aquitain des Sciences de l'Univers (3) IRAM (4) Department of Physics and Astronomy, Colgate University (5) Space Telescope Science Institute (6) Universite de Grenoble (7) Centro de Radioastronomia y Astrofisica, UNAM (8) Stony Brook University)
We aim at unveiling the observational imprint of physical mechanisms that govern planetary formation in the young, multiple system GG Tau A. We present ALMA observations of 12CO and 13CO 3-2 and continuum at 0.9 mm at 0.35" resolution. The 12CO gas, found in the cavity of the dust ring where no 13CO gas is detected, confirms the existence of a CO accretion shock near the circumstellar disk of GG Tau Aa. The outer disk and the hot spot lying at the outer edge of the dust ring are observed both in 12CO and 13CO. The gas emission in the outer disk can be radially decomposed in a series of slightly overlapping gaussian rings, suggesting the presence of unresolved gaps. The dip closest to the disk center lies at a radius very close to the CO hot spot location (~250-260~au). Studies of the CO excitation conditions reveal that the outer disk remains in the shadow of the ring. The hot spot probably results from local heating processes. The two latter points strongly support the hypothesis making the hot spot an embedded proto-planet shepherding the outer disk and accreting surrounding material which may be traced by the the redshifted component observed in the spectra around the hot spot.
Planet-forming Lifeline Discovered in a Binary Star System
For the first time, researchers using ALMA have detected a streamer of gas flowing from a massive outer disc toward the inner reaches of a binary star system. This never-before-seen feature may be responsible for sustaining a second, smaller disc of planet-forming material that otherwise would have disappeared long ago. Half of Sun-like stars are born in binary systems, meaning that these findings will have major consequences for the hunt for exoplanets. The results are published in the journal Nature on 30 October 2014. Read more
Title: Circumbinary Gas Accretion onto a Central Binary: Infrared Molecular Hydrogen Emission from GG Tau A Authors: Tracy L. Beck (1), Jeffrey. S. Bary (2), Anne Dutrey (3), Vincent Piétu (4), Stephane Guilloteau (3), S. H. Lubow (1), M. Simon (5) ((1) STScI, (2) Colgate University, (3) Université de Bordeaux, (4) IRAM, (5) Stony Brook University)
We present high spatial resolution maps of ro-vibrational molecular hydrogen emission from the environment of the GG Tau A binary component in the GG Tau quadruple system. The H2 v= 1-0 S(1) emission is spatially resolved and encompasses the inner binary, with emission detected at locations that should be dynamically cleared on several hundred-year timescales. Extensions of H2 gas emission are seen to ~100 AU distances from the central stars. The v = 2-1 S(1) emission at 2.24 microns is also detected at ~30 AU from the central stars, with a line ratio of 0.05 ±0.01 with respect to the v = 1-0 S(1) emission. Assuming gas in LTE, this ratio corresponds to an emission environment at ~1700 K. We estimate that this temperature is too high for quiescent gas heated by X-ray or UV emission from the central stars. Surprisingly, we find that the brightest region of H2 emission arises from a spatial location that is exactly coincident with a recently revealed dust "streamer" which seems to be transferring material from the outer circumbinary ring around GG Tau A into the inner region. As a result, we identify a new excitation mechanism for ro-vibrational H2 stimulation in the environment of young stars. The H2 in the GG Tau A system appears to be stimulated by mass accretion infall as material in the circumbinary ring accretes onto the system to replenish the inner circumstellar disks. We postulate that H2 stimulated by accretion infall could be present in other systems, particularly binaries and "transition disk" systems which have dust cleared gaps in their circumstellar environments.
Title: The Orbit of GG Tau A Authors: Rainer Köhler
GG Tau A is a pre-main-sequence binary system that is encircled by a circumbinary disk with a sharp inner edge. We present a study of the orbit of the binary system GG Tau A and its relation to the circumbinary disk. Three new relative astrometric positions of the binary were obtained with NACO at the VLT. We combine these with data from the literature and fit orbit models to the dataset. We find that an orbit coplanar with the disk and compatible with the astrometric data is too small to explain the inner gap of the disk. On the other hand, orbits large enough to cause the gap are tilted with respect to the disk. If the disk gap is indeed caused by the stellar companion, then the most likely explanation is a combination of underestimated astrometric errors and a misalignment between the planes of the disk and the orbit.