Post on 24-Feb-2016
description
Photometric Studies of Transiting Exoplanets
Norio Narita (NAOJ)
Transit of Venus on June 5, 2012 at Hawaii
Outline
• Introduction of Transit
• Current Status of Studies of Transiting Exoplanets
• Further Studies of Transiting Exoplanets
• How to Observe Transits by Youeself?
• Summary
What is Transit?
primary eclipse= transit
secondary eclipse
planetary orbit
How to Find Transiting Exoplanets
• We cannot spatially resolve a transiting exoplanet, but we can observe slight dimming due to transits
Methods to search for transiting exoplanets
1. Photometric follow-up of RV known planets
2. Transit survey and RV follow-up
The First Discovery of a Transiting Exoplanet
Charbonneau et al. (2000)Transits of “hot Jupiter” HD209458b
(Possible transit times were predicted by RV)
Transit Survey
One can search for periodic dimming from this kind of data
Some Characteristics of Transiting Planets
stellar radius :
planetary radius :
Toward Earthsemi-major axis :
orbital period :
Transit Probability :Transit Depth :Transit Duration :
~ Rs/a
~ (Rp/Rs)2
~ Rs P/a π
Science Importance of Transiting Planets
• One can learn precise size of planets
– One can also learn true mass and density of planets
when combined with RV
– The information is only available for transiting planets
• Also, transit observations enable us to infer
1. internal structure of planets
2. atmospheric composition of planets
3. orbital migration history (Talk by Hirano tomorrow)
What we can learn from transit light curve
stellar limb-darkeningplanet radius
ratio of planet/star size
stellar radius, orbital inclination, mid-transit time
Analytic transit light curve was modeled by Mandel & Agol (2002)
When combined with RVs
RVs provide minimum mass: Mp sin i
Transits provide planetary radius: Rp
orbital inclination: i
Combined information provides planetary mass: Mp
planetary density: ρ
Inferring Internal Structure of Planets
Charbonneau et al. (2009)
Solid line:H/He dominated
Dashed line:100% H2O
Dotted line:75% H2O, 22% Si, 3% Fe core
Dot-dashed line:Earth-like
Transits revealed varieties of planets’ structure
Transit Spectroscopy / Band Photometry
star
Transit depth depends on lines or bands
Inferring Atmospheric Composition of GJ1214b
Green: H dominated with solar metallicityRed: H dominated with sub-solar metallicity and cloud layer at 0.5 bar
Blue: Vapor dominated atmosphere
de Mooij et al. (2011)
Current Status of Studies of Transiting Exoplanets
The number of transiting planets is rapidly growing.
Dedicated Space Mission for Transiting Planets
CoRoTlaunched 2006/12/27
Keplerlaunched 2009/3/6
Kepler Field of View
TrES-2(Kepler-1)
HAT-P-7(Kepler-2)
HAT-P-11(Kepler-3)
Pre-Kepler Transiting Planets
<1.25 RE
First 4 Month Kepler Planet Candidates
1235 Planet Candidates
2326 Planet Candidates
54 candidates are in
possible habitable zone.
5 are terrestrial size.
Possible Habitable Planet Kepler-22b
(Sub-)Earth-sized Planets
Earth-sized planet Kepler-20f
Mars-sized planet KOI-961.03 (renamed as Kepler-42d)
Now Not a Science Fiction
Planetary Systems with Two Suns: Kepler-16, 34, 35, 47
→ Tatooine-like (in Star Wars) planet
Summary of Current Status
• Various transiting exoplanets have been discovered– hot Jupiters– hot Nuptunes– super Earths– habitable planets– Tatooine-like planets
• We have learned that there are various interesting transiting exoplanets
• What’s next?
Kepler’s Weakness
• Kepler targets relatively faint and far stars
– Although over 1000 candidates discovered, RV follow-ups for all targets are difficult
– Further characterization studies are also difficult
Kepler is good for statistical studies, but not for detailed studies for each planet
Strategy of Future Transit Survey
• Future transit surveys will target nearby bright stars to detect terrestrial planets in habitable zone
• Space-based all-sky transit survey for bright stars– TESS (Transiting Exoplanet Survey Satellite) by MIT team
• Ground-based transit survey for nearby M dwarfs– MEarth lead by D. Charbonneau at Harvard
– Other teams all over the world
– Our IRD transit group (collaborating with UH etc)
What we would like to do
1. To search for new interesting transiting planets orbiting nearby bright stars
2. To characterize nature (internal structure, atmosphere, habitability) of those planets
• To do so, we need to observe transiting exoplanets with high precision!
How to Observe Transits by Yourself
• First you need to get observing time at your university or openuse facilities– not necessarily large telescope for bright targets– Let’s try submitting a proposal
• You can find information of transiting planets and transit ephemeris at– http://exoplanet.eu/catalog/ (Exoplanet.eu)– http://var2.astro.cz/ETD/ (Exoplanet Transit Database)
How to Achieve High Precision Transit Photometry
• High precision (~0.1% or ~1mmag) photometry was considered to be very difficult previously
• A good solution is1. to fix stellar position on the detector during observations
2. with image defocus
Example of Detector Image
Stars are defocused and kept off from bad pixels.
Field of View
~20 pix diameter
Example at Okayama in Japan (J band)
~1mmag is achieved for J~10 target (Fukui et al. in prep.)
Example at Okayama (Ks band)
~1mmag is achieved for Ks~10 target (Ohnuki et al. in prep.)
Example at South Africa / IRSF
~1 mmag is achieved for J < 10 target (Narita et al. 2013)
Example at Subaru Suprime-Cam (B band)
0.8 mmag is achieved for B = 16.4 target! (Narita et al. in prep.)
Let’s try transit observations
• Using the simple technique, we can observe exoplanetary transits with high precision1. to fix stellar position on the detector during observations
2. with image defocus
• If you are interested, you can submit a proposal in your country or other countries’ openuse time!
Summary
• Transits provide us useful information for properties of exoplanets
• Numbers of interesting transiting exoplanets have been discovered
• With the simple technique, you can achieve good precision for transit photometry
• So please try transit photometry by yourself!