PLATO. revealing the interior of planets and stars completing the age of planet discovery for Earth-sized planets constraining planet formation

Similar documents
PLATO Follow-up. Questions addressed. Importance of the follow-up. Importance of the follow-up. Organisa(on*&*Progress*Report

PLATO-2.0 Follow-up. Questions addressed. PLATO Follow-up activities. Mass distribution Spectroscopy. Small mass planets are numerous => huge work

The Physics of Exoplanets

Synergies between E-ELT and space instrumentation for extrasolar planet science

Detection and characterization of exoplanets from space

Professional / Amateur collaborations in exoplanetary science

HD Transits HST/STIS First Transiting Exo-Planet. Exoplanet Discovery Methods. Paper Due Tue, Feb 23. (4) Transits. Transits.

Design Reference Mission. DRM approach

The SPIRou RV surveys. Étienne Artigau for the SPIRou collaboration

Exoplanet Science in the 2020s

Science of extrasolar Planets A focused update

II Planet Finding.

The Kepler Legacy Continues: A Catalog of K2 Planets David R. Ciardi NExScI/Caltech

The Kepler Exoplanet Survey: Instrumentation, Performance and Results

The Search for Habitable Worlds Lecture 3: The role of TESS

Kepler s Multiple Planet Systems

Extrasolar Planets: Ushering in the Era of Comparative Exoplanetology

Discovering Exoplanets Transiting Bright and Unusual Stars with K2

Search for Transiting Planets around Nearby M Dwarfs. Norio Narita (NAOJ)

Update on asteroseismology with Plato

Actuality of Exoplanets Search. François Bouchy OHP - IAP

CHARACTERIZING EXOPLANETS SATELLITE

Extrasolar Planets. Methods of detection Characterization Theoretical ideas Future prospects

TESS and Galactic Science

Searching for Other Worlds

Exoplanets Atmospheres. Characterization of planetary atmospheres. Photometry of planetary atmospheres from direct imaging

Credit: NASA/Kepler Mission/Dana Berry. Exoplanets

Finding Extra-Solar Earths with Kepler. William Cochran McDonald Observatory

Expected asteroseismic performances with the space project PLATO

Pan-Planets. A Search for Transiting Planets Around Cool stars. J. Koppenhoefer, Th. Henning and the Pan-PlanetS Team

Importance of the study of extrasolar planets. Exoplanets Introduction. Importance of the study of extrasolar planets

Can We See Them?! Planet Detection! Planet is Much Fainter than Star!

EarthFinder A NASA-selected Probe Mission Concept Study for input to the 2020 Astrophysics Decadal Survey

Lecture 12: Extrasolar planets. Astronomy 111 Monday October 9, 2017

DETECTING TRANSITING PLANETS WITH COROT. Stefania Carpano ESAC (25th of November 2009)

Exoplanets in Ondrejov ground based support of space missions first results Petr Kabáth ING, La Palma 05 September 2018

HARPS-N Contributions to the Mass-Radius

Exoplanets: the quest for Earth twins

From the first stars to planets

Data from: The Extrasolar Planet Encyclopaedia.

@ CFHT. Isabelle Boisse (LAM) and the SPIRou team France, Canada, CFHT, Brazil, Hawaii, Taiwan, Switzerland & Portugal

PLATO: PLAnetary Transits and Oscillations of stars

Why Search for Extrasolar Planets?

Characterization of the exoplanet host stars. Exoplanets Properties of the host stars. Characterization of the exoplanet host stars

Exoplanets. Saturday Physics for Everyone. Jon Thaler October 27, Credit: NASA/Kepler Mission/Dana Berry

SPIRou status. and the SPIRou team.

Internal structure and atmospheres of planets

Exoplanetary Science with Mul4- Object Spectrographs (and GLAO) Norio Narita (NAOJ)

Planets are plentiful

3.4 Transiting planets

The Galactic Exoplanet Survey Telescope (GEST)

Exoplanets Direct imaging. Direct method of exoplanet detection. Direct imaging: observational challenges

CASE/ARIEL & FINESSE Briefing

Planets and Brown Dwarfs

E-ELT s View of Exoplanetary Atmospheres

New spectrographs for precise RV at ESO

2010 Pearson Education, Inc.

The Large UV Optical IR survey telescope. Debra Fischer

The CHEOPS Mission Consortium David Ehrenreich

How Common Are Planets Around Other Stars? Transiting Exoplanets. Kailash C. Sahu Space Tel. Sci. Institute

Young Solar-like Systems

ASTB01 Exoplanets Lab

Igor Soszyński. Warsaw University Astronomical Observatory

APHRODITE. Ground-Based Observing Team -1-

The Impact of Gaia on Our Knowledge of Stars and Their Planets

Science with EPICS, the E-ELT planet finder

Exoplanetary transits as seen by Gaia

Planet Detection! Estimating f p!

PLAnetary Transits and Oscillations of stars

Habitable Planets: 2 Estimating f s "

Plato, Euclid and the New Hard X-Ray mission

Indirect Methods: gravitational perturbation of the stellar motion. Exoplanets Doppler method

WP the Mass-Radius relationship for gas giants

Chapter 13 Lecture. The Cosmic Perspective Seventh Edition. Other Planetary Systems: The New Science of Distant Worlds Pearson Education, Inc.

The SONG project: past and present (and a little future) Jørgen Christensen-Dalsgaard

White dwarf populations. Gijs Nelemans Radboud University Nijmegen

Earth-like planets in habitable zones around L (and T) dwarfs

Extrasolar Transiting Planets: Detection and False Positive Rejection

Exoplanets Direct imaging. Direct method of exoplanet detection. Direct imaging: observational challenges

Extrasolar planets. Lecture 23, 4/22/14

The Plato Input Catalog (PIC)

Science Olympiad Astronomy C Division Event National Exam

Astronomy. Catherine Turon. for the Astronomy Working Group

Ground Based Gravitational Microlensing Searches for Extra-Solar Terrestrial Planets Sun Hong Rhie & David Bennett (University of Notre Dame)

life detection capabilities of LUVOIR and HabEx and WFIRST

Interferometry & Asteroseismology of Solar-like Stars

Asterosismologia presente e futuro. Studio della struttura ed evoluzione delle stelle per mezzo delle oscillazioni osservate sulla superficie

Doppler Technique Measuring a star's Doppler shift can tell us its motion toward and away from us.

Chapter 13 Lecture. The Cosmic Perspective Seventh Edition. Other Planetary Systems: The New Science of Distant Worlds Pearson Education, Inc.

The Kepler Mission. NASA Discovery Mission # 10: Are there other planets, orbiting other stars, with characteristics similar to Earth?

Exoplanetary Science with the E-ELT

Habitability Outside the Solar System. A discussion of Bennett & Shostak Chapter 11 HNRS 228 Dr. H. Geller

GAPS2: the origin of planetary systems diversity

Exoplanets and The Transiting Exoplanet Survey Satellite (TESS)

Planets & Life. Planets & Life PHYS 214. Please start all class related s with 214: 214: Dept of Physics (308A)

Synergies & Opportunities for SONG in the TESS Era

Chapter 8: The Family of Stars

Angular Resolution Universe. Universe

Probing the Galactic Planetary Census

Asteroseismology with the Kepler mission

Transcription:

PLATO PLAnetary Transits and Oscillations of Stars revealing the interior of planets and stars completing the age of planet discovery for Earth-sized planets constraining planet formation The PLATO Consortium: 501 members from 23 countries (European, Brazil, US, Chile, Canada, Australia) Heike Rauer and the PLATO team

The PLATO mission Techniques: - photometric transits - asteroseismology - ground based spectroscopy for radial velocity Example: Kepler-10b PLATO : - very large samples of bright stars - continuous photometric monitoring from space, in the visible - ultra-high precision - very wide field Accuracy for an Earth around a solar-like star: * planet radius up to 2% * planet mass up to 10% * age known to 10% And much better for larger planets! 2

PLATO current status PLATO consortium applied to ESA to enter the M3 competition. PLATO already finished mission studies during M2 competition. The PLATO consortium will be re-adjusted to fit the M3 timeline (launch 2022/24) The science case is refined in the context of the 2022/24 launch perspective, taking into account recent Kepler and rvsurvey results

Planet Detections

Planet Detections Focus of interest for future space-based transit missions: Detect terrestrial planets up tp the HZ of solar-like stars

Planet diversity Gautier et al. 2012 Fressin et al. 2011 Future transit surveys need to detect Earth-sized planets characterize their radius and mass with high accuracy

Planet diversity Planets and moons in the Solar System Meaningfiul constraints on planet interior require High accury on radius (2%) and mass (10%)

Planet diversity and planet formation Rocky and icy planets Gas giants

Planet diversity and planet formation

Planet diversity and planet formation Planets larger than the critical mass accrete H, He and develop into gas giants.

Planet diversity and planet formation Planets larger than the critical mass accrete H, He and develop into gas giants.

Planet diversity and planet formation Planet free region? Our current understanding of planet formation predicts fast gas envelope accretion beyond 10-15 M earth

Planet diversity and planet formation Circles: upper mass limits available only! Real planet masses are likely to be much lower.

Planet diversity and planet formation? Objects with upper mass limits only orbit faint stars (~15 mag). Need to observe brighter stars. Do massive rocky planets exist? What is the critical mass for giant planet formation? Does it depend on the disc (e.g. dust/gas ratio)?

Planet diversity and planet formation? Objects with upper mass limits only orbit faint stars (~15 mag). Need to observe brighter stars. What is the diversity of Earth-sized planets? Does it depend on orbital distance, stellar type, etc.?

PLATO Selection of science cases: Detect Earth-sized planets in the habitable zone with known radii and masses, including planets orbiting solar-like stars. Obtain statistical significant numbers of characterized small planets at different orbits, stars, Determine the critical mass for gas giant growth Study planet interior composition and structure including terrestrial objects Study planetary systems Determine accurate ages of planet systems Provide small terrestrial planets around bright stars as targets for atmosphere spectroscopy 16

Currently little overlap between current transit and rv surveys Planet radii are obtained by transit observations Planet masses can be derived by radial velocity measurements Transits are detected in broad-band (white light) photometry Radial velocity measurements require high-resolution spectroscopy > much tighter limit on target brightness

Currently little overlap between current transit and rv surveys

Currently little overlap between current transit and rv surveys Need to detect transiting planets around bright stars! Provide targets for spectroscopy characterization! Region of interest for atmosphere characterization

PLATO instrumental concept Very wide field + large collecting area : multi-instrument approach - 32 «normal» cameras : cadence 25 sec - 2 «fast» cameras : cadence 2.5 sec, 2 colours - pupil 120 mm - dynamical range: 4 m V 16 20

Organization of Groundbased follow-up US: several 2m HET 10m Keck 10m OHP 2m Mercator 1.2m Tautenburg 2m Infrared facilities: 1-2 m/s earths around late K - M dwarfs 40 nights/year x 6 years 3 telescopes Spirou CFH 3.6m NOT 2.5m Carmenes CA 3.5m Euler 1.2m ESO 2.2m HARPS-N TNG 3.5m Crires VLT 8m GTC 10m HARPS ESO 3.6m NTT 3.5m Espresso VLT 8m AAT 4m 1-2m-class telescopes: 3-10m/s giant planets on short/medium orbits 100 nights/year x 6 years 6 telescopes 4m-class telescopes: 1-2 m/s giant planets on long orbits super-earths on short/medium orbits 100 nights/year x 6 years 4 telescopes 8m-class telescopes: < 50cm/s super-earths on long orbits, earths on short/medium orbits earths on long orbits @ brightest stars 40 nights/year x 6 years 1 telescope

Current transiting planet findings Kepler candidates are above m V =11 RV confirmation is very difficult no confirmed earth-like planet in HZ expected from Kepler - high accuracy determination of radius and mass - bright hosts stars - very few such targets expected from Kepler Confirmed planets and Kepler candidates 24

PLATO planets versus current transiting planet findings - high accuracy determination of radius and mass - bright hosts stars - very few such targets expected from Kepler PLATO confirmed planet yield for <11mag PLATO will provide a large sample of terrestrial planets, down to Earth size, with highly accurate mass and radius around bright stars up to the habitable zone. 25

Magnitude range of PLATO planets Main PLATO magnitude range

The PLATO legacy - a huge sample of characterized planets with known mass, radius and age, including terrestrial planets in the HZ of solar-like stars - planets surrounding stars bright enough for detailed follow-up pioneers true comparative planotology and taxonomy of planet systems A huge complementary science program: - 1,000,000 of high-precision photometric stellar lightcurves - 85,000 of these stars will allow for astroseismic characterization - in synergy with Gaia: mass, age, rotation, distance, luminosity, radius a breakthrough in stellar physics (e.g. stellar structure and evolution, internal mixing processes, stellar rotation, ages of globular clusters, young open clusters) 27

PLATO Selection of science cases: Detect Earth-sized planets in the habitable zone with known radi and masses, including planets orbiting solar-like stars. Obtain statistical significant numbers of characterized small planets at different orbits, stars, Determine the critical mass for gas giant growth Study planet interior composition and structure including terrestrial objects Study planetary systems Determine accurate ages of planet systems Provide small terrestrial planets around bright stars as targets for atmosphere spectroscopy

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback