NEAR-INFRARED THERMAL EMISSION FROM TrES-3b: A Ks-BAND DETECTION AND AN H-BAND UPPER LIMIT ON THE DEPTH OF THE SECONDARY ECLIPSE

We present H- and Ks-band photometry bracketing the secondary eclipse of the hot Jupiter TrES-3b using the Wide-field Infrared Camera on the Canada-France-Hawaii Telescope. We detect the secondary eclipse of TrES-3b with a depth of 0.133+0.018 ?0.016% in the Ks band (8?)?a result that is in sharp contrast to the eclipse depth reported by de Mooij & Snellen. We do not detect its thermal emission in the H band, but place a 3? limit of 0.051% on the depth of the secondary eclipse in this band. A secondary eclipse of this depth in Ks requires very efficient day-to-nightside redistribution of heat and nearly isotropic reradiation, a conclusion that is in agreement with longer wavelength, mid-infrared Spitzer observations. Our 3? upper limit on the depth of our H-band secondary eclipse also argues for very efficient redistribution of heat and suggests that the atmospheric layer probed by these observations may be well homogenized. However, our H-band upper limit is so constraining that it suggests the possibility of a temperature inversion at depth, or an absorbing molecule, such as methane, that further depresses the emitted flux at this wavelength. The combination of our near-infrared measurements and those obtained with Spitzer suggests that TrES-3b displays a near-isothermal dayside atmospheric temperature structure, whose spectrum is well approximated by a blackbody. We emphasize that our strict H-band limit is in stark disagreement with the best-fit atmospheric model that results from longer wavelength observations only, thus highlighting the importance of near-infrared observations at multiple wavelengths, in addition to those returned by Spitzer in the mid-infrared, to facilitate a comprehensive understanding of the energy budgets of transiting exoplanets.

[1]  Richard S. Freedman,et al.  A Unified Theory for the Atmospheres of the Hot and Very Hot Jupiters: Two Classes of Irradiated Atmospheres , 2007, 0710.2558.

[2]  William Rambold,et al.  WIRCam: the infrared wide-field camera for the Canada-France-Hawaii Telescope , 2004, SPIE Astronomical Telescopes + Instrumentation.

[3]  A. Burrows,et al.  Ks-BAND DETECTION OF THERMAL EMISSION AND COLOR CONSTRAINTS TO CoRoT-1b: A LOW-ALBEDO PLANET WITH INEFFICIENT ATMOSPHERIC ENERGY REDISTRIBUTION AND A TEMPERATURE INVERSION* , 2009 .

[4]  F. Allard,et al.  The NextGen Model Atmosphere Grid for 3000 ≤ Teff ≤ 10,000 K , 1998, astro-ph/9807286.

[5]  D. Saumon,et al.  Atmosphere, Interior, and Evolution of the Metal-rich Transiting Planet HD 149026b , 2006 .

[6]  E. Agol,et al.  Analytic Light Curves for Planetary Transit Searches , 2002, astro-ph/0210099.

[7]  B. Fegley,et al.  Atmospheric Chemistry in Giant Planets, Brown Dwarfs, and Low-Mass Dwarf Stars: I. Carbon, Nitrogen, and Oxygen , 2002 .

[8]  Drake Deming,et al.  A Ground‐based Search for Thermal Emission from the Exoplanet TrES‐1 , 2007, 0705.4288.

[9]  I. Hubeny,et al.  A Possible Bifurcation in Atmospheres of Strongly Irradiated Stars and Planets , 2003 .

[10]  Comparative Planetary Atmospheres: Models of TrES-1 and HD 209458b , 2005, astro-ph/0505359.

[11]  Mercedes Lopez-Morales,et al.  DAY-SIDE z′-BAND EMISSION AND ECCENTRICITY OF WASP-12b , 2009, 0912.2359.

[12]  M. López-Morales,et al.  Thermal Emission from Transiting Very Hot Jupiters: Prospects for Ground-based Detection at Optical Wavelengths , 2007, 0708.0822.

[13]  W. Vacca,et al.  Accepted for publication in ApJ Preprint typeset using L ATEX style emulateapj v. 10/09/06 ATMOSPHERIC PARAMETERS OF FIELD L AND T DWARFS 1 , 2022 .

[14]  David Charbonneau,et al.  An Upper Limit on the Reflected Light from the Planet Orbiting the Star τ Bootis , 1999, astro-ph/9907195.

[15]  Sara Seager,et al.  The Very Low Albedo of an Extrasolar Planet: MOST Space-based Photometry of HD 209458 , 2007, 0711.4111.

[16]  I. Snellen High-precision K-band photometry of the secondary eclipse of HD 209458 , 2005, astro-ph/0507618.

[17]  T. Barman On the Presence of Water and Global Circulation in the Transiting Planet HD 189733b , 2008, 0802.0854.

[18]  Drake Deming,et al.  THE BROADBAND INFRARED EMISSION SPECTRUM OF THE EXOPLANET TrES-3 , 2009, 0909.5221.

[19]  Avi Shporer,et al.  THE TRANSIT LIGHT CURVE PROJECT. VIII. SIX OCCULTATIONS OF THE EXOPLANET TrES-3 , 2008, 0804.2479.

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

[21]  G. Fazio,et al.  The Infrared Array Camera (IRAC) for the Spitzer Space Telescope , 2004, astro-ph/0405616.

[22]  I. Snellen,et al.  Ground-based K-band detection of thermal emission from the exoplanet TrES-3b , 2009, 0901.1878.

[23]  David Lafreniere,et al.  NEAR-INFRARED THERMAL EMISSION FROM THE HOT JUPITER TrES-2b: GROUND-BASED DETECTION OF THE SECONDARY ECLIPSE , 2010, 1005.3027.

[24]  Tristan Guillot,et al.  Atmospheric circulation and tides of ``51 Pegasus b-like'' planets , 2002 .

[25]  E. Covino,et al.  K‐band transit and secondary eclipse photometry of exoplanet OGLE‐TR‐113b , 2006 .

[26]  David Charbonneau,et al.  TrES-3: A Nearby, Massive, Transiting Hot Jupiter in a 31 Hour Orbit , 2007, 0705.2004.

[27]  Drake Deming,et al.  Infrared Observations during the Secondary Eclipse of HD 209458b. II. Strong Limits on the Infrared Spectrum Near 2.2 μm , 2003, astro-ph/0307297.

[28]  I. Hubeny,et al.  Theoretical Spectra and Light Curves of Close-in Extrasolar Giant Planets and Comparison with Data , 2007, 0709.4080.

[29]  Avi Shporer,et al.  THE TRANSIT LIGHT CURVE PROJECT. X. A CHRISTMAS TRANSIT OF HD 17156b , 2008, 0810.4725.

[30]  N. Christensen,et al.  Bayesian methods for cosmological parameter estimation from cosmic microwave background measurements , 2000, astro-ph/0103134.

[31]  Mercedes Lopez-Morales,et al.  Ground-based secondary eclipse detection of the very-hot Jupiter OGLE-TR-56b , 2009, 0901.1876.

[32]  David Charbonneau,et al.  ATMOSPHERIC CIRCULATION OF HOT JUPITERS: COUPLED RADIATIVE-DYNAMICAL GENERAL CIRCULATION MODEL SIMULATIONS OF HD 189733b and HD 209458b , 2008, 0809.2089.

[33]  L. J. Richardson,et al.  On the Dayside Thermal Emission of Hot Jupiters , 2005 .

[34]  M. E. Everett,et al.  A NEW SPECTROSCOPIC AND PHOTOMETRIC ANALYSIS OF THE TRANSITING PLANET SYSTEMS TrES-3 AND TrES-4 , 2008, 0809.4589.

[35]  A. Loeb A Dynamical Method for Measuring the Masses of Stars with Transiting Planets , 2005, astro-ph/0501548.

[36]  Drake Deming,et al.  3.8-μm photometry during the secondary eclipse of the extrasolar planet HD 209458b , 2007, 0704.1306.

[37]  David A. Golimowski,et al.  THE 0.8–14.5 μm SPECTRA OF MID-L TO MID-T DWARFS: DIAGNOSTICS OF EFFECTIVE TEMPERATURE, GRAIN SEDIMENTATION, GAS TRANSPORT, AND SURFACE GRAVITY , 2009, 0906.2991.

[38]  Aisey M Andel ANALYTIC LIGHTCURVES FOR PLANETARY TRANSIT SEARCHES , 2002 .

[39]  PHYSICAL PARAMETERS OF TWO VERY COOL T DWARFS , 2006, astro-ph/0611062.

[40]  David Charbonneau,et al.  Theoretical Spectral Models of the Planet HD 209458b with a Thermal Inversion and Water Emission Bands , 2007, 0709.3980.

[41]  R. Kuschnig,et al.  WATER, METHANE, AND CARBON DIOXIDE PRESENT IN THE DAYSIDE SPECTRUM OF THE EXOPLANET HD 209458b , 2009, 0908.4010.

[42]  I. Hubeny,et al.  Optical Albedo Theory of Strongly Irradiated Giant Planets: The Case of HD 209458b , 2008, 0803.2523.

[43]  Observatoire de Geneve,et al.  VLT transit and occultation photometry for the bloated planet CoRoT-1b , 2009, 0905.4571.

[44]  B. Croll Markov Chain Monte Carlo Methods Applied to Photometric Spot Modeling , 2006 .