1. PTYS 214 – Spring 2011  Homework #10 DUE in class TODAY  Review Guide will be uploaded to class website soon  Class website: http://www.lpl.arizona.edu/undergrad/classes/spring2011/Pierazzo_214 /  Useful Reading: class website  “Reading Material” http://en.wikipedia.org/wiki/Extrasolar_planet http://exoplanet.eu/catalog.php http://www.solstation.com/stars/gl581.htm Announcements

2. Planetary Sciences Graduate Teaching Assistant Excellence Award Planetary Science Department initiative to promote, recognize and reward exemplary performance among graduate teaching assistants assigned to PTYS undergraduate courses If you think your PTYS-214 Teaching Assistant qualifies for the award, please fill out a nomination form describing: 1)Why you are nominating the TA 2)How the TA has contributed to your learning experience After April 25 th, nomination forms and the drop box will be located on the table outside your classroom, room 308 The Teaching Assistants for PTYS214-2 are: Lissa Ong & Devin Schrader

3. HW #9  Total Students: 24  Class Average: 8.2  Low: 3.5  High: 10 Homework is worth 30% of the grade

4. Extrasolar Planets Also called exoplanets, they are planets that orbit other stars beyond our Sun The existence of other solar systems has been suspected for centuries, but verified only in the 1990s

5. In 1995, a breakthrough: the first planet around another star A Swiss team discovers a planet around 51 Pegasi – 50 light years from Earth Artist's concept of an extrasolar planet (Greg Bacon, STScI) 7 Didier Queloz & Michel Mayor

6. And then the discoveries started rolling in: “First new solar system discovered” USA TODAY - April 16, 1999 “10 More Planets Discovered” Washington Post - August 6, 2000 “New Planet Seen Outside Solar System” New York Times - April 19, 1996

7. You can even see some of the stars that have planets in the night sky…

8. …if you know where to look Planet of 70 Virginis =7.42 Jupiter masses Planet of Tau Bootes =4.41 Jupiter masses

9. Just how far are these new planets? from Mars… it would take 3-22 minutes from the nearest extrasolar planet… it would take over ten years! from the Moon… it would take <2 seconds IF YOU WANTED TO RADIO HOME FOR YOUR WORDS TO REACH EARTH

10. Detecting Extra-Solar Planets Problem #1: Planets are not bright objects! Problem #2: Planets are relatively small and close to a bright star (D Sun ~ 10 D Jupiter ~ 100 D Earth ) Successful detection techniques:  Stellar Radial Velocity, or Doppler Method  Planetary Transit  Direct Imaging  Gravitational microlensing

11. Most extrasolar planets orbit very close to their star— “hot Jupiters” As of today (4-21-11) ~544 mostly Jupiter-sized planets (~300 Earth masses) have been discovered ( http://exoplanet.eu/catalog.php)

12. Radial Velocity Technique Most exoplanets (~499) are detected by radial velocity technique Uses the Doppler Effect to measure changes in the radial velocity of a star caused by the small gravitational force of an unseen orbiting planet ….but it can only measure motion along the line of sight (edge on) Allows to determine the planet’s mass plus shape and size of orbit

13. Radial Velocity Technique  Observe red-shifting and blue- shifting of the star’s spectral lines caused by Doppler effect  Amount of blue or red shift corresponds to the star’s radial velocity towards or away from us

14. Planetary Transit Technique Measures dimming of star light as planet passes in front of star Star-light may dim by only 0.000001 (10 -6 ) About 127 planets have been detected by the transit technique

15. Planetary Transit Technique Disadvantages: a) Bias towards large planets and in short period orbits b) False detections due to stellar variability c) Planet’s orbit must be seen edge-on from the observer point of view (so the planet passes in front of the star) Advantages: a) Relatively cheap b) Can determine the size of the planet

16. Direct Imaging  Direct detection of planets is extremely difficult  Rare cases when direct imaging can work are: −Planet is very large (considerably larger than Jupiter) −Planet is widely separated from its parent star −Planet is young (so that it is hot and emits intense infrared radiation)  Few exoplanets are imaged directly  ~21 candidates Image of a planet around GQ Lupi (early K-type star) The planet is believed to be about twice the mass of Jupiter and to have an orbital radius of about 30 AU (similar to Neptune) 2005; European Southern Observ.

18. Gravitational Microlensing  Use the gravitational effect of large objects that can bend light around them  If the object is a star with a planet, the planet can be detected by its effect on the microlensing About 12 potential exoplanets detected by this technique

19.  Several extrasolar planets are Super-Earths, 1-10 times more massive than Earth  The smallest extrasolar planet discovered so far (in 2009) is Gliese 581e, estimated to be about 2 Earth masses  About 20 percent of extrasolar planets are within the Habitable Zone of their parent stars Extrasolar Planets: discovered so far

20. Extrasolar Planets: prediction

21. Most Earth-like: Gliese 581d Gliese 581 is a red dwarf star (about 1/3 the Sun’s mass), located 20.3 light years from Earth PlanetMass Distance (AU) Orbit (days) Eccentr. e2M E 0.033.150 b16M E 0.045.370 c5M E 0.0712.90.17 d7M E 0.2266.80.38 Venus-like? Potential for life?

22. Gliese 581d animation http://www.youtube.com/watch?v=wJXSSYyIVqw http://www.youtube.com/watch?v=_kcquVBYbGw&feature=related

23. Prospects for finding habitable planets  Best candidates are F, G, and early K-type stars, i.e., stars not too different from the Sun  Early-type stars (blue stars) –High UV fluxes –Short life (not enough time for life to evolve)  Late-type stars (red dwarfs) – M-class, M dwarfs –Targets for many habitable, earth-sized planet searches –Examples: GJ 436b, Gl 581c, OGLE-2005-BLG- 390L

24. Hertzsprung- Russell (HR) Diagram

25. Activity Searching for Habitable Planets

26. Stellar Habitable Zone

27.  Much less massive than Sun-like stars (G-type stars)  Deeper transits, better RV detection  Very low luminosity  Smaller HZs Consider an M5 dwarf which has a luminosity L = 0.0055 x L(solar) [Recall L(Solar) = 3.84 x 10 26 W]. At what distance (D) from the M5 dwarf would a planet receive the same total radiation flux of the Earth? [Recall S 0 = 1370 W/m 2 ] Habitable Planets around M dwarf stars

28. So why looking at M dwarf stars?  More numerous than Sun-like stars –Constitute 20 of the 30 stars nearest to Earth  Much longer life spans than Sun-like stars –Some can live for trillions of years!

29. Problems with M-dwarfs  Limited Habitable Zone (too cold?)  Tidal locking (only one face of planet facing star, becomes synchronously rotating)  Stellar variability: lots of flares HOWEVER: A study by Joshi et al. 1997 has shown that atmospheric circulation should help reduce day-night temperature variations. Heath et al. 1999 concluded that even during a flare, radiation received by a planet in the HZ of an M dwarf is comparable to that received by the Earth. These planets could still be habitable!