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Exoplanets in the ELT Era

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Exoplanets in the ELT Era Exoplanets in the ELT Era C. Beichman NASA Exoplanet Science Inst. JPL/CalTech Thanks to Quinn Konopacky, Mike Fitzgerald, Dimitir Mawet © 2019 California Institute of Technology. Government sponsorship acknowledged. What Do ELTs give us relative to 8-10 m telescopes • Greater Collecting Area − Study fainter planets at higher spectral resolution − Study time resolved phenomena, e.g. Rossiter-McLaughlin • Angular resolution with AO − Improved contrast (2l/D on 10 m →6l/D on 30 m) − Resolve inner solar system scales out to 50 pc − Resolve outer solar system scales out to 140 pc • Higher Spectral Resolution − Detailed atmospheric and planet characterization − Rejection of stellar activity for PRV on solar type stars • Synergistic combination of Collecting Area, Angular and Spectral Resolution will revolutionize exoplanet science ELTs will overtake space telescopes for imaging until 2035 and level playing field for planet spectroscopy Science Goals and Methods How Do Giant Planets Form & Evolve? Demographics (Discovery) (Bowler Astro2020 White Paper) • Imaging of young gas/ice/rocky(?) planets • Timescale of giant planet assembly • Masses/orbits of HZ Earths around G stars • Variation of accretion with radial distance • Orbital inclination via Rossiter- McLaughlin • Roles of various molecular “ice lines” • Microlensing follow-up for true masses • Evolution of orbital and angular Characterization (Spectroscopy) momentum • Transiting & non-transiting planets • Importance of different migration – Atomic and molecular abundances mechanisms (disk-planet, planet-planet interactions, or Kozai) – Surface mapping, weather, rotation • Evolution of planet atmospheres – Vertical atmospheric structure • Heavy element enrichment wrt host stars – Unambiguous masses and orbits Can we find biomarkers on nearby • Characterization of protoplanetary disks and Earths? protoplanets Various Instrument Suites Will Take Advantage of ELTs Mode TMT GMT E-ELT Imaging MODHIS: 0.95-2.5 mm GMT-IFS IFU, 1-2.5 MICADO 0.8-2.4 mm ~3x3 IFU, Nuller R~100,000 mm, R<10,000 METIS 3-19 mm PSI-Blue (0.6-1.8 mm), R~50 TIGER 1.5-5 mm, 8- (direct, coronagraphy, NRM) coronagraph w IFU 25 R~300 (high PSI-Red (2-5 mm) R~50-5k contrast) coronagraph w IFU Low PSI-Blue (0.6-1.8 mm), R~50 GMT-NIRS HARMONI (0.47-2.5 mm) R<20k Resl’n coronagraph w IFU 1.1-2.5 mm, R=65k METIS (3-10 mm, R<2k-6k) Spectra PSI-Red (2-5 mm) R~50-5k 3-5.4 R=85k MICADO 0.8-2.4 mm (R<20k) coronagraph w IFU HIRES (0.4-1.8 mm), R~20k High MODHIS. 0.95-2.5 mm G-CLEF (0.36-1.0 METIS (3-5 mm, R~100k) Resl’n Coronagraphy, Nuller mm, R<100,000) HIRES (0.4-1.8 mm),R~150k Spectra R~100,000. 10 cm/s PRV PSI-Blue (0.6-1.8 mm) R~100k TMT/MODHIS. A First Light Instrument • Multi-Object, High Contrast, R~100k Spectral Resolution, 1-2.5 mm Single and multi-object spectroscopy (4-8 • AO-fed, Single Mode Fiber (SMF) makes simultaneous objects, compact, stable, inexpensive instrument including mini-IFU) • Exoplanet spectroscopy, NIR PRV (10 cm/s), galactic and x-gal science High contrast scene, • Heritage from Palomar/PARVI, Keck/HISPEC, Spectroscopic R~100k characterization for Subaru/IRD exoplanets > diffraction • Collaboration with Japan and Canada limit High contrast scene <diffraction limit with Nuller for detection and characterization of exoplanets at 140+ pc Diffraction Limited Spectrometers Using Single Mode Fibers are Compact, Stable, Inexpensive and Real OpticalPossible layout Optical of layout PARVI of HISPEC/MODHIS PARVI spectrum of Barnard’s Star High Resolution Spectroscopy of Giant Planets Atomic and molecular abundances, spin (day), surface mapping, vertical structure, true masses (Snellen 2013) Kelt 9b--Hoeijmakers 2019 Birkby et al 2013 ELTs Will (Finally) Image Exoplanets (And Not Just Failed Brown Dwarfs) Visible & Near IR Exoplanet Strategy Report 2018 Thermal IR TMT/PSI Capabilities at a Glance Imaging Spectroscopy R~100 • Detection and planetary demographics at Low and Moderate R~5k • Bulk atmospheric characterization Spectral Resolution • Detailed molecular abundances High-Resolution • Search for close-in planets R~100k Spectroscopy • Variability, rotation rates (spin), mapping (cloud distribution and dynamics, circulation, etc.) • Increased sample complementing transit+RV 105-108 Contrast and • Access to important range of T , HZs 1-2 λ/D Inner Working Angle (IWA) eq • Enabling study of albedos, energetics TMT-Planetary Systems Imager • Detect and characterize reflected light and thermal emission of rocky planets, ice giants, and gas giants around nearby stars. − Albedos of nearby super-Earths rocky planets • Characterize atmospheric properties − Abundances: CH4, CO, H2O, NH3, PH3 − Cloud depths and composition − Vertical and horizontal structure (Doppler mapping) − Planetary spin rates • Interactions between planets and their disks. − Mass accretion rates and velocity structure of forming exoplanets Giant Planets Less Rare w ELTs Extended• Improved GPI Occurrence survey of Rate from Inner IWA 300Working young Angle,stars (Nielsen Contrast, Sensitivity Nielsen et al 2019 et al− 3.5%2019) (8 -10 m) → 11%->25% (30m) − 5300-13 stars Mo → 30->60 planets • 3-−510 mm-100 2x AU better for contrast Contrast/Sens − 6 planets 30 m 8-10 m to− reach3 Brown given Dwarfs mass • 3.5% occurrence rate Survey Mass Range SMA Relative (MJup) Range Occurrence (AU) (Nielsen 2018) 8-10 m 5-13 10-100 1 (3.5%) 30 m surveys would probe 1 -10 30 m (IWA only) 5-13 3-100 ×3.5 (11%) 30 m (IWA+ 2.5-13 3-100 ×7.2 (25%) Myr, 140 pc samples (Taurus, etc) at contrast) 10-100 AU JWST 0.5-13 15-100 ×3.9 (14%) Study Disks & Protoplanets in Core Accertion Domain Low and high resolution spectroscopy and imaging at the 10 mas (1-5 AU) at 25-140 pc CQ Tau Uyama et al 2019 PDS-70 b and C Subaru’s SEEDS Rogues Gallery Haffert et al 2019 ALMA TW Hya Detecting the Nearest Habitable Zone Worlds With extreme Adaptive Optics performance ELTs may be able to detect reflected light from surfaces (& atmospheres) from Habitable Zone Earths orbiting M stars Mazin et al WP 2020 Kaspar et al 2019 (NEAR Team) Thermal Imaging of Earths VLT/NEAR Obs of Alpha Can AB Orbiting Nearby Stars • VLT/Near demonstrated 3 10-6 at 1” − <5 R in 77 hr • Upgraded VLT/Near could reach <2 R • METIS on EELT ~1 R at 0.5 and 1 AU (400 and 280K) ELT VLT, 2 l/D Brandl et al Proc SPIE, 2016 Finding Biomarkers in an Lopez-Morales et al. 2019, AJ, 158, 24 Earth Transiting an M star • Ultrahigh spectral resolution (R=300-500k) • 20-30 transits with 30 m telescope • Visible and/or NIR O2 (Snellen et al. 2013) • Echelle spectrometer (SMF) or Fabry Perot (Ben Ami et al 2018) Exoplanets in the ELT Era--Conclusions • Angular Resolution reveals interior of planetary systems −Thermal emission (3<l<10 mm !!!) and reflected light imaging −Protoplanetary disks and protoplanets • Collecting Area combined with high resolution spectroscopy for PRV masses/orbits • Collecting Area combined with high contrast and high resolution spectroscopy for atmospheric and physical characterization • Detection and characterization of Earths orbiting closest M stars are within reach. And even 1-2 solar type stars Subarashii Subaru omedetō t Wonderful Subaru Congratulationsh a Demographics of Microlensing targets Exoplanets: Other • WFIRST will find thousands of Extreme Precision Radial Velocity to Detect microlensing planets in the otherwise Earth Analogs Orbiting Solar Analogs inaccessible “snowline” • Imaging w 30 m telescopes will separate • Ultra high resolution (>150,000) and high SNR at lens and source soon after discovery to visible wavelengths for line by line analysis to validate and to disambiguate mass, identify and reject stellar activity (Davis et al distance, etc 2017; Dumusque et al 2018) LeeBhattacharya Astro2020 etWP al 2018 Dumusque et al 2018 Giant Planet Are Rare in 8-10 m Surveys Planets, all stars: 5 MJup < M < 13 Mjup Extended GPI survey of 300 young stars (Nielsen et al 2019) − 0.2Mo to 5Mo − 10-100 AU Brown Dwarfs, all stars: − 6 planets 13 MJup < M< 80 MJup − 3 Brown Dwarfs Nielsen et al 2019 TMT/MODHIS Simulation of 1700 K Planet (1.1 Rjup) orbiting a K4 star Detection of atoms & molecules (CH4, Ca I, H2O, CO), orbital motion Star Planet Mawet et al Transit Signal X-Corr Singal HARMONI CCF Beta Pic planet Houille et al 2019 (Lyot) Absil et al METIS (Lyot) What Do ELTs give us • Inner Working Angle to resolve solar systems, 1-10 AU, out to 140 pc • Sensitivity: time(SNR) D4 ~81 faster than Keck in background limit w AO or D2 ~9 for source photon or read noise limited observations − Time varying observations, e.g. transits, Doppler Mapping, Rossiter McLaughlin − Highest spectral resolution spectroscopy for PRV, faint objects METIS in the infrared L- and M-bands, and HIRES at visible and near- infrared wavelengths. These E-ELT instruments will allow a detailed chemical census of the full population of exoplanets to reveal the diversity of their atmospheres. Excitingly, simulations have also shown that high resolution spectra from the E-ELT instruments will be able to detect a potential oxygen biomarker at 0.76 μm in the atmospheres of Earth-like planets orbiting in the habitable zones of M-dwarf stars, in just a few dozen transits (Snellen et al., 2013). Companion Detection via Near-IR Nulling Interferometry Gene Serabyn and Bertrand Mennesson Nulling interferometry can get closer to a star than coronagraphy - nulling can detect companions to ≈ 1/4 휆/D • Left: Null-depth rotation curve measured with the Palomar Fiber Nuller (PFN) on the 휂 Peg spectroscopic binary. • PFN rotates the Ks-band null fringe within the telescope’s ×× AO-corrected point-spread function.
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