PROBING TRAPPIST-1-LIKE SYSTEMS WITH K2

The search for small planets orbiting late M dwarfs holds the promise of detecting Earth-size planets for which their atmospheres could be characterised within the next decade. The recent discovery of TRAPPIST-1 entertains hope that these systems are common around hosts located at the bottom of the main sequence. In this Letter, we investigate the ability of the repurposed Kepler mission (K2) to probe planetary systems similar to TRAPPIST-1. We perform a consistent data analysis of 189 spectroscopically confirmed M5.5 to M9 late M dwarfs from campaigns 1-6 to search for planet candidates and inject transit signals with properties matching TRAPPIST-1b and c. We find no transiting planet candidates across our K2 sample. Our injection tests show that K2 is able to recover both TRAPPIST-1 planets for 10% of the sample only, mainly because of the inefficient throughput at red wavelengths resulting in Poisson-limited performance for these targets. Increasing injected planetary radii to match GJ1214b's size yields a recovery rate of 70%. The strength of K2 is its ability to probe a large number of cool hosts across the different campaigns, out of which the recovery rate of 10% may turn into bona-fide detections of TRAPPIST-1 like systems within the next two years.

[1]  Frederick Mosteller,et al.  Understanding robust and exploratory data analysis , 1983 .

[2]  G. Kov'acs,et al.  A box-fitting algorithm in the search for periodic transits , 2002, astro-ph/0206099.

[3]  I. Reid,et al.  Meeting the Cool Neighbors. III. Spectroscopy of Northern NLTT Stars , 2002, astro-ph/0202461.

[4]  James Liebert,et al.  Meeting the Cool Neighbors. V. A 2MASS-Selected Sample of Ultracool Dwarfs , 2003, astro-ph/0307429.

[5]  Catherine Slesnick,et al.  A Large-Area Search for Low-Mass Objects in Upper Scorpius. I. The Photometric Campaign and New Brown Dwarfs , 2006 .

[6]  James Liebert,et al.  Meeting the Cool Neighbors. IX. The Luminosity Function of M7-L8 Ultracool Dwarfs in the Field , 2006, astro-ph/0609648.

[7]  J. Bochanski,et al.  CONSTRAINING THE AGE–ACTIVITY RELATION FOR COOL STARS: THE SLOAN DIGITAL SKY SURVEY DATA RELEASE 5 LOW-MASS STAR SPECTROSCOPIC SAMPLE , 2007, 0712.1590.

[8]  R. F. Jameson,et al.  New brown dwarfs in Upper Sco using UKIDSS Galactic Cluster Survey science verification data , 2007 .

[9]  University of Leicester,et al.  The potential for Earth‐mass planet formation around brown dwarfs , 2007, 0709.0676.

[10]  I. Neill Reid,et al.  Meeting the Cool Neighbors. XI. Beyond the NLTT Catalog , 2007 .

[11]  L. Hillenbrand,et al.  A Large-Area Search for Low-Mass Objects in Upper Scorpius. II. Age and Mass Distributions , 2008, 0809.1436.

[12]  Meeting the Cool Neighbors. X. Ultracool Dwarfs from the 2MASS All-Sky Data Release , 2008 .

[13]  Joshua N. Winn,et al.  The Transit Light Curve Project. IX. Evidence for a Smaller Radius of the Exoplanet XO-3b , 2008, 0804.4475.

[14]  Xavier Bonfils,et al.  A super-Earth transiting a nearby low-mass star , 2009, Nature.

[15]  A. Collier Cameron,et al.  The thermal emission of the young and massive planet CoRoT-2b at 4.5 and 8 μm , 2009, 0911.5087.

[16]  T. Owen,et al.  KEPLER MISSION DESIGN, REALIZED PHOTOMETRIC PERFORMANCE, AND EARLY SCIENCE , 2010, 1001.0268.

[17]  G. Basri,et al.  A VOLUME-LIMITED SAMPLE OF 63 M7–M9.5 DWARFS. II. ACTIVITY, MAGNETISM, AND THE FADE OF THE ROTATION-DOMINATED DYNAMO , 2009, 0912.4259.

[18]  W. Benz,et al.  Extrasolar planet population synthesis. III. Formation of planets around stars of different masses , 2011, 1101.0513.

[19]  D. Queloz,et al.  Detection of a transit of the super-Earth 55 Cancri e with warm Spitzer , 2011, 1105.0415.

[20]  A. Fortier,et al.  Planet formation models: the interplay with the planetesimal disc , 2012, 1210.4009.

[21]  D. Apai,et al.  PROTOPLANETARY DISK MASSES FROM STARS TO BROWN DWARFS , 2013, 1305.6896.

[22]  D. Charbonneau,et al.  THE OCCURRENCE RATE OF SMALL PLANETS AROUND SMALL STARS , 2013, 1302.1647.

[23]  A. Fortier,et al.  Theoretical models of planetary system formation: mass vs. semi-major axis , 2013, 1307.4864.

[24]  D. Charbonneau,et al.  CONSTRAINTS ON PLANET OCCURRENCE AROUND NEARBY MID-TO-LATE M DWARFS FROM THE MEarth PROJECT , 2013, 1307.3178.

[25]  Sara Seager,et al.  The future of spectroscopic life detection on exoplanets , 2014, Proceedings of the National Academy of Sciences.

[26]  F. Mullally,et al.  The K2 Mission: Characterization and Early Results , 2014, 1402.5163.

[27]  Y. Alibert On the radius of habitable planets , 2013, 1311.3039.

[28]  A. Vanderburg,et al.  A Technique for Extracting Highly Precise Photometry for the Two-Wheeled Kepler Mission , 2014, 1408.3853.

[29]  Kolby L. Weisenburger,et al.  AN ACTIVITY–ROTATION RELATIONSHIP AND KINEMATIC ANALYSIS OF NEARBY MID-TO-LATE-TYPE M DWARFS , 2015, 1509.01590.

[30]  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.

[31]  Brice-Olivier Demory,et al.  Variability in the super-Earth 55 Cnc e , 2015, 1505.00269.

[32]  S. Aigrain,et al.  K2SC: flexible systematics correction and detrending of K2 light curves using Gaussian process regression , 2016, 1603.09167.

[33]  David J Armstrong,et al.  K2 variable catalogue – II. Machine learning classification of variable stars and eclipsing binaries in K2 fields 0–4 , 2015, 1512.01246.

[34]  P. Magain,et al.  Temperate Earth-sized planets transiting a nearby ultracool dwarf star , 2016, Nature.

[35]  Y. Alibert Constraining the volatile fraction of planets from transit observations , 2016, 1605.05064.