The CARMENES Search for Exoplanets around M Dwarfs: A Low-mass Planet in the Temperate Zone of the Nearby K2-18

K2-18 is a nearby M2.5 dwarf, located at 34 pc and hosting a transiting planet that was first discovered by the K2 mission and later confirmed with Spitzer Space Telescope observations. With a radius of ∼2 R⊕ and an orbital period of ∼33 days, the planet lies in the temperate zone of its host star and receives stellar irradiation similar to that of Earth. Here we perform radial velocity follow-up observations with the visual channel of CARMENES with the goal of determining the mass and density of the planet. We measure a planetary semi-amplitude of Kb ∼ 3.5 and a mass of Mb ∼ 9 M⊕, yielding a bulk density around . This indicates a low-mass planet with a composition consistent with a solid core and a volatile-rich envelope. A signal at 9 days was recently reported using radial velocity measurements taken with the HARPS spectrograph. This was interpreted as being due to a second planet. We see a weaker, time- and wavelength-dependent signal in the CARMENES data set and thus favor stellar activity for its origin. K2-18 b joins the growing group of low-mass planets detected in the temperate zone of M dwarfs. The brightness of the host star in the near-infrared makes the system a good target for detailed atmospheric studies with the James Webb Space Telescope.

[1]  R. P. Butler,et al.  The CARMENES search for exoplanets around M dwarfs , 2018, Astronomy & Astrophysics.

[2]  Landessternwarte,et al.  CARMENES input catalogue of M dwarfs , 2018, Astronomy & Astrophysics.

[3]  Sarah Blunt,et al.  RadVel: The Radial Velocity Modeling Toolkit , 2018, 1801.01947.

[4]  Richard J. Mathar,et al.  The CARMENES search for exoplanets around M dwarfs. HD147379 b : A nearby Neptune in the temperate zone of an early-M dwarf , 2017, 1712.05797.

[5]  Xavier Bonfils,et al.  A temperate exo-Earth around a quiet M dwarf at 3.4 parsec , 2017, 1711.06177.

[6]  Mark S. Giampapa,et al.  The Transit Light Source Effect: False Spectral Features and Incorrect Densities for M-dwarf Transiting Planets , 2017, 1711.05691.

[7]  S. V. Jeffers,et al.  The CARMENES search for exoplanets around M dwarfs : First visual-channel radial-velocity measurements and orbital parameter updates of seven M-dwarf planetary systems , 2017, 1710.01595.

[8]  S. V. Jeffers,et al.  Spectrum radial velocity analyser (SERVAL). High-precision radial velocities and two alternative spectral indicators , 2017, 1710.10114.

[9]  Andrew Cumming,et al.  Near-InfraRed Planet Searcher to Join HARPS on the ESO 3.6-metre Telescope , 2017 .

[10]  Observatoire de Paris,et al.  The Ca II infrared triplet's performance as an activity indicator compared to Ca II H and K , 2017, 1708.04895.

[11]  X. Delfosse,et al.  Characterization of the K2-18 multi-planetary system with HARPS: A habitable zone super-Earth and discovery of a second, warm super-Earth on a non-coplanar orbit , 2017, 1707.04292.

[12]  Christoph Mordasini,et al.  Compositional Imprints in Density–Distance–Time: A Rocky Composition for Close-in Low-mass Exoplanets from the Location of the Valley of Evaporation , 2017, 1706.00251.

[13]  Joseph E. Rodriguez,et al.  A temperate rocky super-Earth transiting a nearby cool star , 2017, Nature.

[14]  C. S. Fernandes,et al.  Seven temperate terrestrial planets around the nearby ultracool dwarf star TRAPPIST-1 , 2017, Nature.

[15]  S. V. Jeffers,et al.  CARMENES: an overview six months after first light , 2016, Astronomical Telescopes + Instrumentation.

[16]  Erik Petigura,et al.  SPITZER OBSERVATIONS CONFIRM AND RESCUE THE HABITABLE-ZONE SUPER-EARTH K2-18b FOR FUTURE CHARACTERIZATION , 2016, 1610.07249.

[17]  L. F. Sarmiento,et al.  A terrestrial planet candidate in a temperate orbit around Proxima Centauri , 2016, Nature.

[18]  Suvrath Mahadevan,et al.  PROXIMA CENTAURI AS A BENCHMARK FOR STELLAR ACTIVITY INDICATORS IN THE NEAR-INFRARED , 2016, 1608.06291.

[19]  W. Seifert,et al.  CARMENES: data flow , 2016, Astronomical Telescopes + Instrumentation.

[20]  U. Exeter,et al.  A path towards understanding the rotation-activity relation of M dwarfs with K2 mission, X-ray and UV data , 2016, 1608.00772.

[21]  Daniel Foreman-Mackey,et al.  corner.py: Scatterplot matrices in Python , 2016, J. Open Source Softw..

[22]  D. Ciardi,et al.  Radial Velocity Planet Detection Biases at the Stellar Rotational Period , 2016, 1604.03143.

[23]  David Charbonneau,et al.  THE IMPACT OF STELLAR ROTATION ON THE DETECTABILITY OF HABITABLE PLANETS AROUND M DWARFS , 2016, 1604.03135.

[24]  Klaus G. Strassmeier,et al.  Transmission spectroscopy of HAT-P-32b with the LBT: confirmation of clouds/hazes in the planetary atmosphere , 2016, 1603.09136.

[25]  Stephen J. Roberts,et al.  Ghost in the time series: no planet for Alpha Cen B , 2015, 1510.05598.

[26]  Dimitar Sasselov,et al.  MASS–RADIUS RELATION FOR ROCKY PLANETS BASED ON PREM , 2015, 1512.08827.

[27]  A. Hatzes Periodic Halpha variations in GL 581: Further evidence for an activity origin to GL 581d , 2015, 1512.00878.

[28]  I. Ribas,et al.  Transmission spectroscopy of the inflated exo-Saturn HAT-P-19b , 2015, 1506.05685.

[29]  W. Cochran,et al.  Long-lived, long-period radial velocity variations in Aldebaran: A planetary companion and stellar activity , 2015, 1505.03454.

[30]  Astrophysics,et al.  STELLAR ACTIVITY MIMICS A HABITABLE-ZONE PLANET AROUND KAPTEYN’S STAR , 2015, 1505.02778.

[31]  John Asher Johnson,et al.  STELLAR AND PLANETARY PROPERTIES OF K2 CAMPAIGN 1 CANDIDATES AND VALIDATION OF 17 PLANETS, INCLUDING A PLANET RECEIVING EARTH-LIKE INSOLATION , 2015, 1503.07866.

[32]  Guillem Anglada-Escudé,et al.  Comment on “Stellar activity masquerading as planets in the habitable zone of the M dwarf Gliese 581” , 2015, Science.

[33]  B. J. Fulton,et al.  A NEARBY M STAR WITH THREE TRANSITING SUPER-EARTHS DISCOVERED BY K2 , 2015, 1501.03798.

[34]  Shane Jacobson,et al.  Extra-solar planets exploration using frequency comb: Infrared Doppler instrument for the Subaru telescope (IRD) , 2012, 2015 Optical Fiber Communications Conference and Exhibition (OFC).

[35]  A. Wolfgang,et al.  HOW ROCKY ARE THEY? THE COMPOSITION DISTRIBUTION OF KEPLER’S SUB-NEPTUNE PLANET CANDIDATES WITHIN 0.15 AU , 2014, 1409.2982.

[36]  Astrophysics,et al.  DISENTANGLING PLANETS AND STELLAR ACTIVITY FOR GLIESE 667C , 2014, 1409.0021.

[37]  L. Rogers MOST 1.6 EARTH-RADIUS PLANETS ARE NOT ROCKY , 2014, 1407.4457.

[38]  W. Seifert,et al.  CARMENES instrument overview , 2014, Astronomical Telescopes and Instrumentation.

[39]  Arpita Roy,et al.  Stellar activity masquerading as planets in the habitable zone of the M dwarf Gliese 581 , 2014, Science.

[40]  Simon Thibault,et al.  SPIRou: the near-infrared spectropolarimeter/high-precision velocimeter for the Canada-France-Hawaii telescope , 2014, Astronomical Telescopes and Instrumentation.

[41]  Shawn Domagal-Goldman,et al.  HABITABLE ZONES AROUND MAIN-SEQUENCE STARS: DEPENDENCE ON PLANETARY MASS , 2014, 1404.5292.

[42]  London,et al.  Flat-relative optimal extraction A quick and efficient algorithm for stabilised spectrographs , 2013, 1311.5263.

[43]  Prasanth H. Nair,et al.  Astropy: A community Python package for astronomy , 2013, 1307.6212.

[44]  A. Hatzes THE RADIAL VELOCITY DETECTION OF EARTH-MASS PLANETS IN THE PRESENCE OF ACTIVITY NOISE: THE CASE OF α CENTAURI Bb , 2013, 1305.4960.

[45]  R. Deshpande,et al.  HABITABLE ZONES AROUND MAIN-SEQUENCE STARS: NEW ESTIMATES , 2013, 1301.6674.

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

[47]  F. Bouchy,et al.  An Earth-mass planet orbiting α Centauri B , 2012, Nature.

[48]  Suvrath Mahadevan,et al.  The habitable-zone planet finder: a stabilized fiber-fed NIR spectrograph for the Hobby-Eberly Telescope , 2012, Other Conferences.

[49]  Jonathan J. Fortney,et al.  HOW THERMAL EVOLUTION AND MASS-LOSS SCULPT POPULATIONS OF SUPER-EARTHS AND SUB-NEPTUNES: APPLICATION TO THE KEPLER-11 SYSTEM AND BEYOND , 2012, 1205.0010.

[50]  R. Paul Butler,et al.  THE HARPS-TERRA PROJECT. I. DESCRIPTION OF THE ALGORITHMS, PERFORMANCE, AND NEW MEASUREMENTS ON A FEW REMARKABLE STARS OBSERVED BY HARPS , 2012, 1202.2570.

[51]  X. Delfosse,et al.  Long-term magnetic activity of a sample of M-dwarf stars from the HARPS program I. Comparison of activity indices , 2011, 1109.0321.

[52]  F. Bouchy,et al.  Disentangling between stellar activity and planetary signals , 2010, Proceedings of the International Astronomical Union.

[53]  Daniel C. Fabrycky,et al.  RADIAL VELOCITY PLANETS DE-ALIASED: A NEW, SHORT PERIOD FOR SUPER-EARTH 55 Cnc e , 2010, 1005.4050.

[54]  J. Bean,et al.  DETECTING PLANETS AROUND VERY LOW MASS STARS WITH THE RADIAL VELOCITY METHOD , 2009, 0909.0002.

[55]  Jan Swevers,et al.  Ground-based and airborne instrumentation for astronomy , 2010 .

[56]  Michael Wegner,et al.  Ground-based and Airborne Instrumentation for Astronomy III , 2010 .

[57]  M. Zechmeister,et al.  The generalised Lomb-Scargle periodogram. A new formalism for the floating-mean and Keplerian periodograms , 2009, 0901.2573.

[58]  Roman V. Baluev,et al.  Accounting for velocity jitter in planet search surveys , 2007, 0712.3862.

[59]  John D. Hunter,et al.  Matplotlib: A 2D Graphics Environment , 2007, Computing in Science & Engineering.

[60]  F. Bouchy,et al.  The HARPS search for southern extra-solar planets. X. A m sin i = 11 M_â planet around the nearby spotted M dwarf GJ 674 , 2007, 0704.0270.

[61]  I. McLean,et al.  Ground-based and Airborne Instrumentation for Astronomy , 2006 .

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

[63]  C. Broeg,et al.  A new algorithm for differential photometry: computing anoptimum artificial comparison star , 2005 .

[64]  Frank Dionies,et al.  The STELLA robotic observatory , 2004 .

[65]  E. Ford Quantifying the Uncertainty in the Orbits of Extrasolar Planets , 2003, astro-ph/0305441.

[66]  The University of Texas at Austin,et al.  The low-level radial velocity variability in Barnard's star (= GJ 699) ? Secular acceleration, indications for convective redshift, and planet mass limits , 2003, astro-ph/0303528.

[67]  A. P. Hatzes,et al.  Starspots and exoplanets , 2002 .

[68]  S. Baliunas,et al.  Patterns of Variation among Sun-like Stars , 1998 .

[69]  Robert A. Donahue,et al.  Activity-Related Radial Velocity Variation in Cool Stars , 1997 .

[70]  E. Bertin,et al.  SExtractor: Software for source extraction , 1996 .

[71]  D. Seckel,et al.  Variation of the solar neutrino flux with the Sun's activity , 1990, Nature.