Atmospheric characterization of terrestrial exoplanets in the mid-infrared: biosignatures, habitability, and diversity

Exoplanet science is one of the most thriving fields of modern astrophysics. A major goal is the atmospheric characterization of dozens of small, terrestrial exoplanets in order to search for signatures in their atmospheres that indicate biological activity, assess their ability to provide conditions for life as we know it, and investigate their expected atmospheric diversity. None of the currently adopted projects or missions, from ground or in space, can address these goals. In this White Paper, submitted to ESA in response to the Voyage 2050 Call, we argue that a large space-based mission designed to detect and investigate thermal emission spectra of terrestrial exoplanets in the mid-infrared wavelength range provides unique scientific potential to address these goals and surpasses the capabilities of other approaches. While NASA might be focusing on large missions that aim to detect terrestrial planets in reflected light, ESA has the opportunity to take leadership and spearhead the development of a large mid-infrared exoplanet mission within the scope of the “Voyage 2050” long-term plan establishing Europe at the forefront of exoplanet science for decades to come. Given the ambitious science goals of such a mission, additional international partners might be interested in participating and contributing to a roadmap that, in the long run, leads to a successful implementation. A new, dedicated development program funded by ESA to help reduce development and implementation cost and further push some of the required key technologies would be a first important step in this direction. Ultimately, a large mid-infrared exoplanet imaging mission will be needed to help answer one of humankind’s most fundamental questions: “How unique is our Earth?”

[1]  B. Brown Proceedings of the Society of Photo-optical Instrumentation Engineers , 1975 .

[2]  S. Seager,et al.  Exoplanet Atmospheres , 2010 .

[3]  Simon Gross,et al.  Towards a photonic mid-infrared nulling interferometer in chalcogenide glass. , 2019, Optics express.

[4]  C. Moutou,et al.  The HARPS search for southern extra-solar planets , 2004, Astronomy & Astrophysics.

[5]  E. Serabyn,et al.  NULLING DATA REDUCTION AND ON-SKY PERFORMANCE OF THE LARGE BINOCULAR TELESCOPE INTERFEROMETER , 2016, 1601.06866.

[6]  S. Seager,et al.  BIOSIGNATURE GASES IN H2-DOMINATED ATMOSPHERES ON ROCKY EXOPLANETS , 2013, 1309.6016.

[7]  Helmut Lammer,et al.  On the (anticipated) diversity of terrestrial planet atmospheres , 2015 .

[8]  Eric B. Ford,et al.  PROBABILISTIC MASS–RADIUS RELATIONSHIP FOR SUB-NEPTUNE-SIZED PLANETS , 2015, 1504.07557.

[9]  Shawn Domagal-Goldman,et al.  DETECTING AND CONSTRAINING N2 ABUNDANCES IN PLANETARY ATMOSPHERES USING COLLISIONAL PAIRS , 2015, 1507.07945.

[10]  F. Bouchy,et al.  The HARPS search for southern extra-solar planets - XXXI. The M-dwarf sample , 2011, 1111.5019.

[11]  Laura Kreidberg,et al.  PROSPECTS FOR CHARACTERIZING THE ATMOSPHERE OF PROXIMA CENTAURI b , 2016, 1608.07345.

[12]  Lucas Labadie,et al.  Progress towards instrument miniaturisation for mid-IR long-baseline interferometry , 2018 .

[13]  H. Rauer,et al.  Searching for Atmospheric Bioindicators in Planets around the Two Nearby Stars, Proxima Centauri and Epsilon Eridani-Test Cases for Retrieval of Atmospheric Gases with Infrared Spectroscopy. , 2019, Astrobiology.

[14]  W. Wadsworth,et al.  Low loss silica hollow core fibers for 3-4 μm spectral region. , 2012, Optics express.

[15]  M. R. Haas,et al.  TERRESTRIAL PLANET OCCURRENCE RATES FOR THE KEPLER GK DWARF SAMPLE , 2015, 1506.04175.

[16]  Eric B. Ford,et al.  Occurrence Rates of Planets Orbiting FGK Stars: Combining Kepler DR25, Gaia DR2, and Bayesian Inference , 2019, The Astronomical Journal.

[17]  Juan Antonio Belmonte,et al.  Handbook of Exoplanets , 2018 .

[18]  Ulf Bestmann,et al.  InfraRed Astronomy Satellite Swarm Interferometry (IRASSI): Overview and study results , 2019, Advances in Space Research.

[19]  Vincenzo Spagnolo,et al.  Single mode operation with mid-IR hollow fibers in the range 5.1-10.5 µm. , 2015, Optics express.

[20]  D. Kipping,et al.  PROBABILISTIC FORECASTING OF THE MASSES AND RADII OF OTHER WORLDS , 2016, 1603.08614.

[21]  Sara Seager,et al.  TOWARD THE MINIMUM INNER EDGE DISTANCE OF THE HABITABLE ZONE , 2013, 1304.3714.

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

[23]  M. Langlois,et al.  Society of Photo-Optical Instrumentation Engineers , 2005 .

[24]  Kyle L. Luther,et al.  CHARACTERIZING TRANSITING EXOPLANET ATMOSPHERES WITH JWST , 2015, 1511.05528.

[25]  Tomohiro Kamiya,et al.  Laboratory demonstration of a cryogenic deformable mirror for wavefront correction of space-borne infrared telescopes. , 2017, Applied optics.

[26]  M. Janson The relevance of prior inclination determination for direct imaging of Earth-like planets , 2010, 1006.2941.

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

[28]  K. Jucks,et al.  Remote sensing of planetary properties and biosignatures on extrasolar terrestrial planets. , 2002, Astrobiology.

[29]  Remko Stuik,et al.  Combining high-dispersion spectroscopy with high contrast imaging : Probing rocky planets around our nearest neighbors , 2015, 1503.01136.

[30]  Khadeejah A. Zamudio,et al.  PLANETARY CANDIDATES OBSERVED BY KEPLER. VII. THE FIRST FULLY UNIFORM CATALOG BASED ON THE ENTIRE 48-MONTH DATA SET (Q1–Q17 DR24) , 2015, 1512.06149.

[31]  E. Serabyn,et al.  The HOSTS Survey for Exozodiacal Dust: Observational Results from the Complete Survey , 2020 .

[32]  Von Welch,et al.  Reproducing GW150914: The First Observation of Gravitational Waves From a Binary Black Hole Merger , 2016, Computing in Science & Engineering.

[33]  X. Delfosse,et al.  Atmospheric characterization of Proxima b by coupling the Sphere high-contrast imager to the Espresso spectrograph , 2016, 1609.03082.

[34]  Lucas Labadie,et al.  Integrated optics prototype beam combiner for long baseline interferometry in the L and M bands , 2017, 1704.05846.

[35]  H Rauer,et al.  Evolution of Earth-like Extrasolar Planetary Atmospheres: Assessing the Atmospheres and Biospheres of Early Earth Analog Planets with a Coupled Atmosphere Biogeochemical Model. , 2018, Astrobiology.

[36]  Shiladitya DasSarma,et al.  Exoplanet Biosignatures: Understanding Oxygen as a Biosignature in the Context of Its Environment , 2017, Astrobiology.

[37]  Drake Deming,et al.  Clouds in the atmosphere of the super-Earth exoplanet GJ 1214b , 2013, Nature.

[38]  Franck Selsis,et al.  3D climate modeling of close-in land planets: Circulation patterns, climate moist bistability and habitability , 2013, 1303.7079.

[39]  Aki Roberge,et al.  MAXIMIZING THE ExoEarth CANDIDATE YIELD FROM A FUTURE DIRECT IMAGING MISSION , 2014, 1409.5128.

[40]  Exoplanet Interferometry Technology Milestone # 3 Report Broadband Starlight Suppression Demonstration , 2009 .

[41]  Andrew Cumming,et al.  The California-Kepler Survey. V. Peas in a Pod: Planets in a Kepler Multi-planet System Are Similar in Size and Regularly Spaced , 2017, 1706.06204.

[42]  H. Rauer,et al.  Clouds in the atmospheres of extrasolar planets II. Thermal emission spectra of Earth-like planets influenced by low and high-level clouds , 2011, 1105.3568.

[43]  Shawn Domagal-Goldman,et al.  Exoplanet Classification and Yield Estimates for Direct Imaging Missions , 2018, 1802.09602.

[44]  E. Serabyn,et al.  The HOSTS Survey—Exozodiacal Dust Measurements for 30 Stars , 2018, 1803.11265.

[45]  Yuka Fujii,et al.  Detecting Ocean Glint on Exoplanets Using Multiphase Mapping , 2018, The Astronomical Journal.

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

[47]  Peter G. Tuthill,et al.  Optical and Infrared Interferometry and Imaging VI , 2016 .

[48]  Dmitry Savransky,et al.  The Gemini Planet Imager Exoplanet Survey: Giant Planet and Brown Dwarf Demographics from 10 to 100 au , 2019, The Astronomical Journal.

[49]  M. Ireland,et al.  THE IMPACT OF STELLAR MULTIPLICITY ON PLANETARY SYSTEMS. I. THE RUINOUS INFLUENCE OF CLOSE BINARY COMPANIONS , 2016, 1604.05744.

[50]  P. Gondoin,et al.  Performance study of ground-based infrared Bracewell interferometers. Application to the detection o , 2005, astro-ph/0511223.

[51]  S. Rabien,et al.  First direct detection of an exoplanet by optical interferometry , 2019, Astronomy & Astrophysics.

[52]  S. P. Quanz,et al.  Simulating the Exoplanet Yield of a Space-based MIR Interferometer Based on Kepler Statistics , 2017, 1707.06820.

[53]  Ian J. M. Crossfield,et al.  On high-contrast characterization of nearby, short-period exoplanets with giant segmented-mirror telescopes , 2013, 1301.5884.

[54]  P. Giommi,et al.  The PLATO 2.0 mission , 2013, 1310.0696.

[55]  GrenfellJohn Lee,et al.  Exoplanet Biosignatures: A Review of Remotely Detectable Signs of Life , 2018 .

[56]  F. Selsis,et al.  Spectral features of Earth-like planets and their detectability at different orbital distances around F, G, and K-type stars , 2013, 1302.5516.

[57]  Sascha P. Quanz,et al.  Direct detection of exoplanets in the 3–10 μm range with E-ELT/METIS , 2014, International Journal of Astrobiology.

[58]  E. Serabyn,et al.  The path towards high-contrast imaging with the VLTI: the Hi-5 project , 2018, Experimental Astronomy.

[59]  T. Trautmann,et al.  Characterization of potentially habitable planets: Retrieval of atmospheric and planetary properties from emission spectra , 2013, 1301.0217.

[60]  A. Olivier,et al.  Improving Interferometric Null Depth Measurements using Statistical Distributions: Theory and First Results with the Palomar Fiber Nuller , 2011, 1103.4719.

[61]  Alistair Glasse,et al.  The Mid-Infrared Instrument for the James Webb Space Telescope, IX: Predicted Sensitivity , 2015, 1508.02427.

[62]  Bernard Muschielok,et al.  The 4MOST instrument concept overview , 2014, Astronomical Telescopes and Instrumentation.

[63]  K. Ulaczyk,et al.  One or more bound planets per Milky Way star from microlensing observations , 2012, Nature.

[64]  S. T. Timmer,et al.  First M87 Event Horizon Telescope Results. I. The Shadow of the Supermassive Black Hole , 2019, 1906.11238.

[65]  Drake Deming,et al.  A continuum from clear to cloudy hot-Jupiter exoplanets without primordial water depletion , 2016, Nature.

[66]  Brice-Olivier Demory,et al.  Atmospheric reconnaissance of the habitable-zone Earth-sized planets orbiting TRAPPIST-1 , 2018, 1802.02250.

[67]  L. Kaltenegger How to Characterize Habitable Worlds and Signs of Life , 2017, 1911.05597.

[68]  B. Macintosh,et al.  Characterizing Earth Analogs in Reflected Light: Atmospheric Retrieval Studies for Future Space Telescopes , 2018, 1803.06403.

[69]  Dimitri Mawet,et al.  Darwin—an experimental astronomy mission to search for extrasolar planets , 2009 .

[70]  H. Rauer,et al.  Clouds in the atmospheres of extrasolar planets - I. Climatic effects of multi-layered clouds for Earth-like planets and implications for habitable zones , 2010, 1002.2927.

[71]  Tyler Robinson,et al.  Observing the Atmospheres of Known Temperate Earth-sized Planets with JWST , 2017, 1708.04239.

[72]  Ryan C. Terrien,et al.  HABITABLE ZONES AROUND MAIN-SEQUENCE STARS: NEW ESTIMATES , 2013, 1301.6674.

[73]  Enzo Pascale,et al.  UvA-DARE (Digital Academic Repository) A chemical survey of exoplanets with ARIEL , 2022 .

[74]  Stefan Martin,et al.  High performance testbed for four-beam infrared interferometric nulling and exoplanet detection. , 2012, Applied optics.

[75]  D. Charbonneau,et al.  THE OCCURRENCE OF POTENTIALLY HABITABLE PLANETS ORBITING M DWARFS ESTIMATED FROM THE FULL KEPLER DATASET AND AN EMPIRICAL MEASUREMENT OF THE DETECTION SENSITIVITY , 2015, 1501.01623.

[76]  A. Szentgyorgyi,et al.  Optimizing Ground-based Observations of O2 in Earth Analogs , 2019, The Astronomical Journal.

[77]  E. Ford,et al.  Vegetation's red edge: a possible spectroscopic biosignature of extraterrestrial plants. , 2005, Astrobiology.

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

[79]  Olivier Absil,et al.  Interferometric Space Missions for Exoplanet Science: Legacy of Darwin/TPF , 2017 .