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Directed Follow-Up of Gaia Photometry in Search of Transiting Planets. Shay Zucker Yifat Dzigan Tel-Aviv University. Dzigan & Zucker , MNRAS, 415, 2513, 2011 Dzigan & Zucker , ApJL , 753, L1, 2012 Dzigan & Zucker ,, MNRAS, accepted.
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Directed Follow-Up of Gaia Photometry in Search of Transiting Planets Shay Zucker YifatDzigan Tel-Aviv University • Dzigan & Zucker, MNRAS, 415, 2513, 2011 • Dzigan & Zucker, ApJL, 753, L1, 2012 • Dzigan & Zucker,, MNRAS, accepted
Aposteriori Detection of HD209458b in Hipparcos Data Söderhjelm 1999 Robichon & Arenou 2000 Castellano et al. 2000
Why not a real detection? • No one believed it was possible • Photometry not precise enough • Low cadence Can we use the data for detection somehow?
Directed Follow-Up – General Idea • Actually sampled transits provide some knowledge about the period, phase, duration and depth of a hypothetical transit, if it exists. • Using MCMC we can present this scarce information as a Probability Distribution Function over (P,Tc,w,d) (assuming a BLS-like model). • For each future time – t, we can use this PDF to calculate an instantaneous transit probability – ITP(t) • Each new follow-up observataion is added and the process is repeated.
Lessons from Hipparcos HD209458Exercise • With five sampled transits, low cadence data, augmented by DFU, allow detection. • Data become useless after a few years. • For completeness – we should mention HD189733b.
Testing DFU on Gaia • Simulated Gaia light curves inspired by known transiting planets (period and duration, coordinates) • Gaia scanning law • Phase chosen to produce required number of sampling transits • Photon noise level – 1 mmag. • We defined three scenarios of detection.
First Scenario – Gaia data alone • Gaia samples enough transits to allow detection of the transit using only Gaia data. • 1-mmag precision makes this scenario possible. • Simulation inspired by CoRoT-1b (P=1.51 d, w=0.1 d) • Assuming five sampled transits (Ntot=64) • d > 0.005 mag
Second Scenario – one DFU observation • Gaia samples enough transits to allow several possible solutions. One DFU observation is enough to constrain the period. • Simulation inspired by CoRoT-4b (P=9.20 d, w=0.16 d) • Assuming three sampled transits (Ntot=63) • d > 0.001 mag
Third Scenario – Few DFU Observations • Gaia samples enough transits to allow several possible solutions. A few DFU observations are needed to constrain the period. • Simulation inspired by WASP-4b (P=1.338 d, w=0.104 d) • Assuming four sampled transits (Ntot=83) • d= 0.005 mag
Third Scenario – Few DFU Observations Only Gaia data Gaia data + 1 DFU observation Gaia data + 2 DFU observations
We shouldn’t wait till the last minute • ITP deteriorates over time • Therefore – we should start observing even before the end of the mission • Tres-1b, (P=3.03 d, w=0.104 d) • Three sampled tranists (Ntot=48) (mid-life of mission) • Assume d=0.008 mag
Is it worth it? Observational Window Function 70 Gaia Measurements 130 Gaia Measurements
Is it worth it? • Assuming 2 hr transit, Galactic model, transiting planet statistics from complete surveys (OGLE) • Down to 14th G magnitude: minimum 7 transits: ~70 transiting HJs and VHJs minimum 5 transits: ~200 minimum 3 transits: ~600 • Down to 16thG magnitude: minimum 7 transits: ~300 transiting HJs and VJHs minimum 5 transits: ~900 minimum 3 transits: ~2600
To do list: • Get organized • Dedicated observatory network? • CU7 follow-up network? • Science Alert team? • Prescreening scheme (metallicity, brightness, activity etc.) • Develop a more efficient computational scheme than MCMC. • Objective criteria for applying DFU • Wald statistics • ITP values • ITP skewness • Smaller planets (Neptunian and below?) • Other low-cadence surveys
Additional slides Contingencies for potential questions