论文信息 - Orbital and atmospheric characterization of the planet within the gap of the PDS 70 transition disk - 字舞流文

Orbital and atmospheric characterization of the planet within the gap of the PDS 70 transition disk

Context. The observation of planets in their formation stage is a crucial but very challenging step in understanding when, how, and where planets form. PDS 70 is a young pre-main sequence star surrounded by a transition disk, in the gap of which a planetary-mass companion has recently been discovered. This discovery represents the first robust direct detection of such a young planet, possibly still at the stage of formation. Aims. We aim to characterize the orbital and atmospheric properties of PDS 70 b, which was first identified on May 2015 in the course of the SHINE survey with SPHERE, the extreme adaptive-optics instrument at the VLT. Methods. We obtained new deep SPHERE/IRDIS imaging and SPHERE/IFS spectroscopic observations of PDS 70 b. The astrometric baseline now covers 6 yr, which allowed us to perform an orbital analysis. For the first time, we present spectrophotometry of the young planet which covers almost the entire near-infrared range (0.96–3.8 μm). We use different atmospheric models covering a large parameter space in temperature, log g, chemical composition, and cloud properties to characterize the properties of the atmosphere of PDS 70 b. Results. PDS 70 b is most likely orbiting the star on a circular and disk coplanar orbit at ~22 au inside the gap of the disk. We find a range of models that can describe the spectrophotometric data reasonably well in the temperature range 1000–1600 K and log g no larger than 3.5 dex. The planet radius covers a relatively large range between 1.4 and 3.7 RJ with the larger radii being higher than expected from planet evolution models for the age of the planet of 5.4 Myr. Conclusions. This study provides a comprehensive data set on the orbital motion of PDS 70 b, indicating a circular orbit and a motion coplanar with the disk. The first detailed spectral energy distribution of PDS 70 b indicates a temperature typical of young giant planets. The detailed atmospheric analysis indicates that a circumplanetary disk may contribute to the total planetflux.

T. Fusco | Julien H. Girard | A. Vigan | T. Moulin | E. Stadler | A. Boccaletti | M. Langlois | A. Zurlo | S. Desidera | D. Mesa | Z. Wahhaj | S. P. Quanz | J. Girard | R. Ligi | G. Chauvin | D. Rouan | K. Molaverdikhani | C. Lazzoni | Th. Henning | A. Pavlov | A.-M. Lagrange | M. Bonnefoy | A.-L. Maire | F. Cantalloube | M. Janson | J. Hagelberg | M. Keppler | M. Feldt | E. Sissa | J.-L. Baudino | M. Samland | M. Gennaro | A. Muller | R. Gratton | M. Meyer | A. Cheetham | F. Menard | J. Ramos | L. Weber | T. Fusco | A. Boccaletti | J. Girard | D. Rouan | A. Maire | G. Chauvin | A. Lagrange | H. Beust | M. Bonnefoy | S. Quanz | M. Meyer | T. Henning | M. Feldt | R. Gratton | M. Langlois | A. Pavlov | E. Stadler | M. Janson | F. Ménard | S. Desidera | D. Mesa | T. Moulin | A. Vigan | J. Hagelberg | B. Charnay | K. Molaverdikhani | L. Weber | C. Mordasini | M. Benisty | F. Cantalloube | R. Boekel | Z. Wahhaj | H. Beust | M. Benisty | M. Meyer | P. Mollière | J. Ramos | M. Gennaro | R. Ligi | C. Mordasini | A. Cheetham | J. Ramos | M. Samland | N. Pawellek | E. Sissa | M. Keppler | A. Muller | A. Zurlo | J. Baudino | C. Lazzoni | P. Molliere | B. Charnay | R. vanBoekel | Z. C. Long | C. Mordasini | N. Pawellek | Z. Long | A. Müller | R. vanBoekel

[1] D. Mawet,et al. Searching for companions down to 2 AU from β Pictoris using the L′-band AGPM coronagraph on VLT/NACO , 2013, 1311.4298.

[2] B. Macintosh,et al. Angular Differential Imaging: A Powerful High-Contrast Imaging Technique , 2005, astro-ph/0512335.

[3] C. Mordasini,et al. Characterization of exoplanets from their formation III: The statistics of planetary luminosities , 2017, 1708.00868.

[4] David Mouillet,et al. Photometric characterization of exoplanets using angular and spectral differential imaging , 2010, 1004.4825.

[5] Daniel Foreman-Mackey,et al. emcee: The MCMC Hammer , 2012, 1202.3665.

[6] D. Mawet,et al. Coronagraphic imaging of three weak-line T Tauri stars: evidence of planetary formation around PDS 70 , 2006 .

[7] Andrew S. Ackerman,et al. Precipitating Condensation Clouds in Substellar Atmospheres , 2001, astro-ph/0103423.

[8] F. Allard,et al. New evolutionary models for pre-main sequence and main sequence low-mass stars down to the hydrogen-burning limit , 2015, 1503.04107.

[9] Kjetil Dohlen,et al. The infra-red dual imaging and spectrograph for SPHERE: design and performance , 2008, Astronomical Telescopes + Instrumentation.

[10] C. Fabron,et al. SPHERE: a planet finder instrument for the VLT , 2006, Astronomical Telescopes + Instrumentation.

[11] L. Abe,et al. Apodized Lyot coronagraph for SPHERE/VLT , 2011 .

[12] G. Chabrier. Galactic Stellar and Substellar Initial Mass Function , 2003, astro-ph/0304382.

[13] A. Vigan,et al. Spectral and atmospheric characterization of 51 Eridani b using VLT/SPHERE , 2017, 1704.02987.

[14] M. H. Montgomery,et al. MODULES FOR EXPERIMENTS IN STELLAR ASTROPHYSICS (MESA): PLANETS, OSCILLATIONS, ROTATION, AND MASSIVE STARS , 2013, 1301.0319.

[15] Gaia Collaboration,et al. The Gaia mission , 2016, 1609.04153.

[16] T. Henning,et al. MODEL ATMOSPHERES OF IRRADIATED EXOPLANETS: THE INFLUENCE OF STELLAR PARAMETERS, METALLICITY, AND THE C/O RATIO , 2015, 1509.07523.

[17] Timothy D. Brandt,et al. THE MEASUREMENT, TREATMENT, AND IMPACT OF SPECTRAL COVARIANCE AND BAYESIAN PRIORS IN INTEGRAL-FIELD SPECTROSCOPY OF EXOPLANETS , 2016, 1602.00691.

[18] M. Mayor,et al. A Jupiter-mass companion to a solar-type star , 1995, Nature.

[19] T. A. Lister,et al. Gaia Data Release 2. Summary of the contents and survey properties , 2018, 1804.09365.

[20] Timothy D. Brandt,et al. THE STRUCTURE OF PRE-TRANSITIONAL PROTOPLANETARY DISKS. I. RADIATIVE TRANSFER MODELING OF THE DISK+CAVITY IN THE PDS 70 SYSTEM , 2012, 1209.3772.

[21] Olivier Guyon,et al. POLARIMETRIC IMAGING OF LARGE CAVITY STRUCTURES IN THE PRE-TRANSITIONAL PROTOPLANETARY DISK AROUND PDS 70: OBSERVATIONS OF THE DISK , 2012, 1208.2075.

[22] J. Wisniewski,et al. Differences in the Gas and Dust Distribution in the Transitional Disk of a Sun-like Young Star, PDS 70 , 2018, 1804.00529.

[23] D. Fantinel,et al. Discovery of a planetary-mass companion within the gap of the transition disk around PDS 70 , 2018, Astronomy & Astrophysics.

[24] Aaron Dotter,et al. MESA ISOCHRONES AND STELLAR TRACKS (MIST) 0: METHODS FOR THE CONSTRUCTION OF STELLAR ISOCHRONES , 2016, 1601.05144.

[25] Anthony Boccaletti,et al. A Self-consistent Cloud Model for Brown Dwarfs and Young Giant Exoplanets: Comparison with Photometric and Spectroscopic Observations , 2017, 1711.11483.

[26] Eric B. Ford,et al. Improving the Efficiency of Markov Chain Monte Carlo for Analyzing the Orbits of Extrasolar Planets , 2005, astro-ph/0512634.

[27] Jieun Choi,et al. MESA ISOCHRONES AND STELLAR TRACKS (MIST). I. SOLAR-SCALED MODELS , 2016, 1604.08592.

[28] T. Fusco,et al. First light of the VLT planet finder SPHERE: I. Detection and characterization of the substellar companion GJ 758 B , 2015, 1511.04076.

[29] Dean M. Townsley,et al. MODULES FOR EXPERIMENTS IN STELLAR ASTROPHYSICS (MESA): BINARIES, PULSATIONS, AND EXPLOSIONS , 2015, 1506.03146.

[30] A. Boccaletti,et al. Azimuthal asymmetries in the debris disk around HD 61005: A massive collision of planetesimals? , 2016, 1601.07861.

[31] A. Boccaletti,et al. Orbital characterization of the β Pictoris b giant planet , 2012, 1202.2655.

[32] E. Ford. QUANTIFYING THE UNCERTAINTY IN THE ORBITS OF EXTRASOLAR PLANETS , 2003, astro-ph/0305441.

[33] E. Mamajek,et al. The star formation history and accretion-disc fraction among the K-type members of the Scorpius–Centaurus OB association , 2016, 1605.08789.

[34] Paul M. Brunet,et al. The Gaia mission , 2013, 1303.0303.

[35] John T. Rayner,et al. SpeX: A Medium‐Resolution 0.8–5.5 Micron Spectrograph and Imager for the NASA Infrared Telescope Facility , 2003 .

[36] D. Fantinel,et al. Performance of the VLT Planet Finder SPHERE - II. Data analysis and results for IFS in laboratory , 2015, 1503.02486.

[37] V. De Caprio,et al. SPHERE IFS: the spectro differential imager of the VLT for exoplanets search , 2008, Astronomical Telescopes + Instrumentation.

[38] Kjetil Dohlen,et al. SPHERE: a planet finder instrument for the VLT , 2006, Astronomical Telescopes + Instrumentation.

[39] Frank Timmes,et al. MODULES FOR EXPERIMENTS IN STELLAR ASTROPHYSICS (MESA) , 2010, 1009.1622.

[40] Pierre-Olivier Lagage,et al. Observing transiting planets with JWST. Prime targets and their synthetic spectral observations , 2016, 1611.08608.

[41] Francois Rigaut,et al. Performance of the near-infrared coronagraphic imager on Gemini-South , 2008, Astronomical Telescopes + Instrumentation.

[42] C. Dorrer,et al. Design, analysis, and testing of a microdot apodizer for the Apodized Pupil Lyot Coronagraph , 2008, 0810.5678.

[43] J. Mathis,et al. The relationship between infrared, optical, and ultraviolet extinction , 1989 .

[44] A. Vigan,et al. Astrometric and photometric accuracies in high contrast imaging: The SPHERE speckle calibration tool (SpeCal) , 2018, Astronomy & Astrophysics.

[45] David Mouillet,et al. SPHERE data reduction and handling system: overview, project status, and development , 2008, Astronomical Telescopes + Instrumentation.

[46] David Mouillet,et al. NAOS, the first AO system of the VLT: on-sky performance , 2003, SPIE Astronomical Telescopes + Instrumentation.