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Transcript
Search for Extra-Solar Planets George Lebo 16 November 2012 AST 2037 1 Eclipsing (Transiting) Binary Light Curve Kepler Spacecraft – 2009 Earth Trailing Orbit Kepler ExoPlanets Solar Coronagraph Vortex Coronagraph Direct Imaging Using a Vortex Coronagraph - HR8799 Beta Pictoris (Very Young Star) Imaging With a Coronagraph Animation URL http://nsfgov.wmsvc.vitalstreamcdn.com/nsfgov_vitalstream_com/microlens.wmv Planets Around Other Stars • None known prior to 1992 (!) • In 1992, Alex Wolczan discovered 2 (now 3) planets around a neutron star • But those seemed weird • Probably supernova leftover bits • In 1995, Michel Mayor & Didier Queloz discover a planet around 51 Pegasi – how? 11 Kepler’s Laws • Kepler described 3 “laws” of planetary motion (for our solar system) • Kepler did not have a physical basis for the laws (i.e. Newton’s laws of motion) • He just found patterns in the motions of planets and used them to develop 3 guidelines that provided a good matching description • Newton later used his physical laws of motion to show WHY Kepler’s rules for planet motion worked 12 Kepler’s First Law • • • • Planet orbits are ELLIPSES (what’s that?) The sun/star is at one “focus” of the ellipse Both the planet and the star orbit the center of mass The distance from the center to the focus is c=ae where e is the “eccentricity” • Circles are ellipses with eccentricity=0 (both foci at center) 13 Kepler’s Second Law • Planet motion sweeps out equal areas of the ellipse in equal time • Meaning … planet moves faster when it is closer to the star and slower when it is farther away 14 Kepler’s Third Law • • • • a3/P2 = Mtot a = semi-major axis of the ellipse (AU) P = period of the orbit (years) Mtot = total mass of the system (solar masses) 15 Orbital Reflex Motion • For a star/planet system, the planet does most of the moving • Its low mass means it is farthest from the center of mass • Same period, larger distance means higher velocity (what is it for Earth? For Jupiter?) • But you can’t see it (too faint) • Star moves VERY little • High mass, means small distance from COM (what is it for Sun/Earth? Sun/Jupiter?) • But we can SEE the star! 16 Barycenter (Center of Mass) of the Solar System http://www.youtube.com/watch?v=ZQ4iQO25IDU Radial Velocity Planet Searches • So … need a speedometer to measure star velocity versus time • To a precision of a few meters per second! • Across distances of many light years!!! • How? Doppler shift of spectral lines 18 Radial Velocity Planet Searches • How-to, with movie • http://static.howstuffworks.com/flash/planet-hunting-radmethod.swf • Take a spectrum with a big telescope and very precise (and STABLE) spectrograph 19 Radial Velocity: Information • Jupiter has biggest reflex velocity effect on the Sun • but this velocity is still small • period is long • Information we get • Period (how?) • Orbit distance (how?) • Eccentricity • Planet mass (note uncertainty!) • Really planet MINIMUM mass! 20 51 Pegasi • In 1995, Mayor & Queloz announce the discovery of an orbital signature with amplitude = 50 m/s in a 4.23day period around star 51 Pegasi • Mass = 0.5 MJUP First extra-solar planet 21 51 Pegasi: Sky View 22 51 Pegasi: Hot Jupiter? 51 Peg period indicates a VERY small orbital radius (P = 4.2 days, a = 0.05 AU) 23 51 Pegasi: Hot Jupiter? • At that location, expected temperature is VERY high (about 2000K or higher!) • So … Jupiter-like planet, but closer than Mercury “Hot Jupiter” • How do you make something like that???? 24 Planet Bonanza • Geoff Marcy & Paul Butler quickly confirmed 51 Pegasi • They had lots of archival data from searches for Jupiter-type planets (periods >10 years, so they were still “in progress”) • No one even thought to look for short-period MASSIVE planets (why would they be easier?) • Found many “Hot Jupiters” – most extra-solar planets known today are Hot Jupters • “MARVELS” (Multi-object Apache Point Observatory Radial Velocity Exoplanet Large-area Survey) is the UF’s program launched in 2008 that promises to be one of the most prolific of all exoplanet hunting programs. 25 ES-Planet Population • As of November 14, 2012, there are 850 known extrasolar planets(!!) and 611 extrasolar planetary systems. • All of this has happened in about 20 years – someone currently finds a new planet every couple of weeks or less • These planets are NOT generally like our Solar System objects – WHY? • Next time: properties of Extra-Solar Planets and implications for Life in the Universe 26
