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OBSERVATIONAL STUDIESOF TRANSITING
EXTRASOLAR PLANETS
John Southworth
Keele University, UK
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Extrasolar planets – a history
• 1995: first extrasolar planet: 51Peg
– Mayor & Queloz (1995)
51 Peg velocity curve
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Extrasolar planets – a history
• 1995: first extrasolar planet: 51Peg
– Mayor & Queloz (1995)
• 1999: first transiting: HD209458
– Charbonneau et al. (2000)
– Henry et al. (2000)
Charbonneau et al. (2000)
Henry et al. (2000)
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Extrasolar planets – a history
• 1995: first extrasolar planet: 51Peg
– Mayor & Queloz (1995)
• 1999: first transiting: HD209458
– Charbonneau et al. (2000)
– Henry et al. (2000)
• 2002: first planet discoveredfrom transits: OGLE-TR-56
– Konacki et al. (2003)
OGLE light curve
Velocities from Torres et al. (2004)
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Extrasolar planets – a history
• 1995: first extrasolar planet: 51Peg
– Mayor & Queloz (1995)
• 1999: first transiting: HD209458
– Charbonneau et al. (2000)
– Henry et al. (2000)
• 2002: first planet discoveredfrom transits: OGLE-TR-56
– Konacki et al. (2003)
• Current census:
– ∼1800 planets in total
– ∼1150 are transiting
OGLE light curve
Velocities from Torres et al. (2004)
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Finding transits
• Dedicated robotic telescopes
– e.g. SuperWASP
– 8 cameras with 200mm lenses
– 483deg2 per observation
– 14′′ per pixel
WASP-South installation (South Africa)
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Finding transits
• Dedicated robotic telescopes
– e.g. SuperWASP
– 8 cameras with 200mm lenses
– 483deg2 per observation
– 14′′ per pixel
• Light curves of millionsof bright stars
– SuperWASP: 18 million objectsaverage 10 000 datapoints each
– search for shallow transits
– get many types of variable stars
WASP-South installation (South Africa)
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Finding transits
• Dedicated robotic telescopes
– e.g. SuperWASP
– 8 cameras with 200mm lenses
– 483deg2 per observation
– 14′′ per pixel
• Light curves of millionsof bright stars
– SuperWASP: 18 million objectsaverage 10 000 datapoints each
– search for shallow transits
– get many types of variable stars
• Or go to space:
– Past: Kepler and CoRoT
– Future: TESS and PLATO
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Are they planets?
• False positives: not all transits are due to planets
– Eclipsing binaries can mimic planet transits
– Low-mass stars and brown dwarfs can have similar radius as a planet
– WASP-South claim success rate 1 in 14; Kepler much higher
Mass–radius plot from planets to low-mass stars
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Are they planets?
• False positives: not all transits are due to planets
– Eclipsing binaries can mimic planet transits
– Low-mass stars and brown dwarfs can have similar radius as a planet
– WASP-South claim success rate 1 in 14; Kepler much higher
• Solution: spectroscopy
– Precise radial velocities give mass
– Observables:KA orbital velocity amplitudee orbital eccentricityω argument of periastron
HARPS spectrograph (credit: ESO)
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Are they planets?
• False positives: not all transits are due to planets
– Eclipsing binaries can mimic planet transits
– Low-mass stars and brown dwarfs can have similar radius as a planet
– WASP-South claim success rate 1 in 14; Kepler much higher
• Solution: spectroscopy
– Precise radial velocities give mass
– Observables:KA orbital velocity amplitudee orbital eccentricityω argument of periastron
– Also get nature of parent star:
Teff effective temperaturelog g surface gravity[
Fe
H
]
metallicityHARPS spectrograph (credit: ESO)
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Follow-up light curves
• Transit shape vital for analysis
– directly yields stellar density
• Ground-based survey photometryusually very scattered
• Need follow-up light curves
SuperWASP data for WASP-103 (Gillon et al., 2014)
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Follow-up light curves
• Transit shape vital for analysis
– directly yields stellar density
• Ground-based survey photometryusually very scattered
• Need follow-up light curves
• Telescope defocussing is excellent:
– collect more photons per image
– pixel response averaged out
– tracking errors less important
SuperWASP data for WASP-103 (Gillon et al., 2014)
PSFs in focus (left) and defocussed (right)
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Follow-up light curves
• Transit shape vital for analysis
– directly yields stellar density
• Ground-based survey photometryusually very scattered
• Need follow-up light curves
• Telescope defocussing is excellent:
– collect more photons per image
– pixel response averaged out
– tracking errors less important
• Example: WASP-103
– orbital period 0.926 days
– defocussed photometry: lightcurve scatter of 0.6 mmag
SuperWASP data for WASP-103 (Gillon et al., 2014)
PSFs in focus (left) and defocussed (right)
Follow-up light curve of WASP-103 (submitted)
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Example: WASP-2
Discovery light curve(Collier Cameron et al. 2007)
σ = 10mmag
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Example: WASP-2
Discovery light curve(Collier Cameron et al. 2007)
σ = 10mmag
Charbonneau et al. (2007)σ = 1.9mmag
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Example: WASP-2
Discovery light curve(Collier Cameron et al. 2007)
σ = 10mmag
Charbonneau et al. (2007)σ = 1.9mmag
Defocussed-photometry light curve(Southworth et al. 2009)
σ = 0.46mmag
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Anatomy of a transit light curve
Light curve gives: Porb orbital period
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Anatomy of a transit light curve
Light curve gives: Porb orbital periodrA = RA/a fractional radius of star
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Anatomy of a transit light curve
Light curve gives: Porb orbital periodrA = RA/a fractional radius of stark = rb/rA ratio of planet to star radius
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Anatomy of a transit light curve
Light curve gives: Porb orbital periodrA = RA/a fractional radius of stark = rb/rA ratio of planet to star radiusi inclination of the orbit
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Getting the physical properties
• Light curve: Porb rA k i
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Getting the physical properties
• Light curve: Porb rA k i
• Radial velocities:
– stellar velocity amplitude KA
– orbital eccentricity e
– can’t observe the velocity amplitude of the planet, Kb
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Getting the physical properties
• Light curve: Porb rA k i
• Radial velocities:
– stellar velocity amplitude KA
– orbital eccentricity e
– can’t observe the velocity amplitude of the planet, Kb
• Spectral synthesis: stellar Teff and[
Fe
H
]
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Getting the physical properties
• Light curve: Porb rA k i
• Radial velocities:
– stellar velocity amplitude KA
– orbital eccentricity e
– can’t observe the velocity amplitude of the planet, Kb
• Spectral synthesis: stellar Teff and[
Fe
H
]
• Interpolate in stellar models:
– find best-fitting mass for the star
– find most likely age for the system
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Getting the physical properties
• Light curve: Porb rA k i
• Radial velocities:
– stellar velocity amplitude KA
– orbital eccentricity e
– can’t observe the velocity amplitude of the planet, Kb
• Spectral synthesis: stellar Teff and[
Fe
H
]
• Interpolate in stellar models:
– find best-fitting mass for the star
– find most likely age for the system
• Get planet mass and radius
⇒ surface gravity ⇒ atmosphere studies
⇒ density ⇒ composition and core size
⇒ composition and core size ⇒ formation scenario
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Getting the physical properties
• Light curve: Porb rA k i
• Radial velocities:
– stellar velocity amplitude KA
– orbital eccentricity e
– can’t observe the velocity amplitude of the planet, Kb
• Spectral synthesis: stellar Teff and[
Fe
H
]
• Interpolate in stellar models:
– find best-fitting mass for the star
– find most likely age for the system
• Get planet mass and radius
⇒ surface gravity ⇒ atmosphere studies
⇒ density ⇒ composition and core size
⇒ composition and core size ⇒ formation scenario
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The additional constraint
• One additional constraint is needed
– Observations do not give an unique solution for the physical properties
– Theoretical stellar models are usually used ⇒ results are not empirical
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The additional constraint
• One additional constraint is needed
– Observations do not give an unique solution for the physical properties
– Theoretical stellar models are usually used ⇒ results are not empirical
• Solution: calibrations from eclipsing binaries
– First try: M–R relation(Southworth, 2009, MNRAS, 394, 272)
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The additional constraint
• One additional constraint is needed
– Observations do not give an unique solution for the physical properties
– Theoretical stellar models are usually used ⇒ results are not empirical
• Solution: calibrations from eclipsing binaries
– First try: M–R relation(Southworth, 2009, MNRAS, 394, 272)
– M and R from Teff , log g ,[
Fe
H
]
(Torres et al., 2010, A&ARv, 18, 67)
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The additional constraint
• One additional constraint is needed
– Observations do not give an unique solution for the physical properties
– Theoretical stellar models are usually used ⇒ results are not empirical
• Solution: calibrations from eclipsing binaries
– First try: M–R relation(Southworth, 2009, MNRAS, 394, 272)
– M and R from Teff , log g ,[
Fe
H
]
(Torres et al., 2010, A&ARv, 18, 67)
– M and R from Teff , ρ,[
Fe
H
]
(Enoch et al., 2010, A&A, 516, A33)
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The additional constraint
• One additional constraint is needed
– Observations do not give an unique solution for the physical properties
– Theoretical stellar models are usually used ⇒ results are not empirical
• Solution: calibrations from eclipsing binaries
– First try: M–R relation(Southworth, 2009, MNRAS, 394, 272)
– M and R from Teff , log g ,[
Fe
H
]
(Torres et al., 2010, A&ARv, 18, 67)
– M and R from Teff , ρ,[
Fe
H
]
(Enoch et al., 2010, A&A, 516, A33)
– Use 90 rather than 19 dEBs(Southworth, 2011, MNRAS,417, 2166)
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The additional constraint
• One additional constraint is needed
– Observations do not give an unique solution for the physical properties
– Theoretical stellar models are usually used ⇒ results are not empirical
• Solution: calibrations from eclipsing binaries
– First try: M–R relation(Southworth, 2009, MNRAS, 394, 272)
– M and R from Teff , log g ,[
Fe
H
]
(Torres et al., 2010, A&ARv, 18, 67)
– M and R from Teff , ρ,[
Fe
H
]
(Enoch et al., 2010, A&A, 516, A33)
– Use 90 rather than 19 dEBs(Southworth, 2011, MNRAS,417, 2166)
• Do we believe eclipsing binaries?
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Alternatives
• Transit timing variations (TTVs):
– gravitational perturbations shift transit times
– transit times give planet masses
– problems: difficult minimisation, low precision
– only worked for Kepler planets so far: e.g. Kepler-11, Kepler-51
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Alternatives
• Transit timing variations (TTVs):
– gravitational perturbations shift transit times
– transit times give planet masses
– problems: difficult minimisation, low precision
– only worked for Kepler planets so far: e.g. Kepler-11, Kepler-51
• Planet validation:
– shallow transits unlikely to be false positives
– calculate probabilities of each type of false positive
– e.g. 851 Kepler planets validated (Rowe et al., 2014, ApJ, 784, 45)
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Alternatives
• Transit timing variations (TTVs):
– gravitational perturbations shift transit times
– transit times give planet masses
– problems: difficult minimisation, low precision
– only worked for Kepler planets so far: e.g. Kepler-11, Kepler-51
• Planet validation:
– shallow transits unlikely to be false positives
– calculate probabilities of each type of false positive
– e.g. 851 Kepler planets validated (Rowe et al., 2014, ApJ, 784, 45)
• Doppler beaming:
– stars are brighter when moving towards us
– detecting this gives planet mass
– e.g. Kepler-76 (Faigler et al., 2013, ApJ, 771, 26)
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Total number of transiting planets: 1142
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Homogeneous studies of transiting planets
Light curve of WASP-2 (Southworth et al. 2009)
• Light curve fit: jktebop
• Limb darkening:
– five different laws
• Contaminating light
• Numerical integration
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Homogeneous studies of transiting planets
Light curve of WASP-2 (Southworth et al. 2009)
• Light curve fit: jktebop
• Limb darkening:
– five different laws
• Contaminating light
• Numerical integration
• Error analyses
– white noise: Monte Carlo
– red noise: residual permutation
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Homogeneous studies of transiting planets
Light curve of WASP-2 (Southworth et al. 2009)
• Light curve fit: jktebop
• Limb darkening:
– five different laws
• Contaminating light
• Numerical integration
• Error analyses
– white noise: Monte Carlo
– red noise: residual permutation
• Physical properties:
– additional constraint: five different stellar theoretical models
– results also using an eclipsing binary calibration
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Homogeneous studies of transiting planets
Light curve of WASP-2 (Southworth et al. 2009)
• Light curve fit: jktebop
• Limb darkening:
– five different laws
• Contaminating light
• Numerical integration
• Error analyses
– white noise: Monte Carlo
– red noise: residual permutation
• Physical properties:
– additional constraint: five different stellar theoretical models
– results also using an eclipsing binary calibration
• Now done 114 transiting systems
• Southworth (2008, 2009, 2010, 2011, 2012) + in prep.
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TEPCat
http://www.astro.keele.ac.uk/jkt/tepcat/
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TEPCat
http://www.astro.keele.ac.uk/jkt/tepcat/
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TEPCat
http://www.astro.keele.ac.uk/jkt/tepcat/
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TEPCat
http://www.astro.keele.ac.uk/jkt/tepcat/
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Rossiter-McLaughlin effect
• Spectroscopic anomaly during transit
– transiting planet blocks out partof the rotating stellar surface
– spectral line broadening no longersymmetric
– causes radial velocity anomaly
HD 189733 (Winn et al., 2006, ApJ, 653, L69)
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Rossiter-McLaughlin effect
• Spectroscopic anomaly during transit
– transiting planet blocks out partof the rotating stellar surface
– spectral line broadening no longersymmetric
– causes radial velocity anomaly
• Anomaly shape depends on orbitalobliquity, ψ
– ψ is angle between orbitalaxis and stellar spin axis
– we acutally measure λ,the sky-projected obliquity
– RM is a window on thedynamical history
HD 189733 (Winn et al., 2006, ApJ, 653, L69)
WASP-15 (Triaud et al., 2010, A&A, 524, A25)
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Orbital obliquity from starspots
• Starspots cause mini-brighteningsduring transit
– measure spot position,size and brightness
– multiple observations give spotmotion
– can yield orbital obliquity
Starspot anomalies in transits of WASP-19
(Tregloan-Reed et al., 2013, MNRAS, 428, 3671)
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Orbital obliquity from starspots
• Starspots cause mini-brighteningsduring transit
– measure spot position,size and brightness
– multiple observations give spotmotion
– can yield orbital obliquity
• Example: WASP-19
– λ = 1.0± 1.2 degrees
– three anomalies could give ψ
Starspot anomalies in transits of WASP-19
(Tregloan-Reed et al., 2013, MNRAS, 428, 3671)
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Occultations
• Planet passes behind star
– drop in brightness gives fluxfrom dayside of planet
– infrared: thermal emission
– optical: reflected starlight
Spitzer light curves of occultations in the HD 189733 system
(Charbonneau et al., 2008, ApJ, 686, 1341)
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Occultations
• Planet passes behind star
– drop in brightness gives fluxfrom dayside of planet
– infrared: thermal emission
– optical: reflected starlight
• most from the Spitzer satellite
– ground-based detections possible(e.g. Lendl et al., 2013, A&A, 552, A2)
Spitzer light curves of occultations in the HD 189733 system
(Charbonneau et al., 2008, ApJ, 686, 1341)
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Occultations
• Planet passes behind star
– drop in brightness gives fluxfrom dayside of planet
– infrared: thermal emission
– optical: reflected starlight
• most from the Spitzer satellite
– ground-based detections possible(e.g. Lendl et al., 2013, A&A, 552, A2)
• Time of occultation gives e cosω:lower limit on orbital eccentricity
Spitzer light curves of occultations in the HD 189733 system
(Charbonneau et al., 2008, ApJ, 686, 1341)
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Transmission spectroscopy
• Observe transit atmultiple wavelengths
– opacity changesaffect theradius measuredfrom transits
– measure opacity atlimb of the planet
Transmission spectrum of HD189733 b
(Pont et al., 2013, MNRAS, 432, 2917)
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Transmission spectroscopy
• Observe transit atmultiple wavelengths
– opacity changesaffect theradius measuredfrom transits
– measure opacity atlimb of the planet
• Results
– some planets have large radii in the blue ⇒ Rayleigh or Mie scattering
– some planets have a featureless spectrum ⇒ clouds
– some planets show VO, TiO and Na in the optical
– some planets show H2O, CO2, CH4 in the infrared
Transmission spectrum of HD189733 b
(Pont et al., 2013, MNRAS, 432, 2917)
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Future – from the ground
• Current surveys
– WASP, HAT, HAT-South, KELT
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Future – from the ground
• Current surveys
– WASP, HAT, HAT-South, KELT
• Forthcoming: NGTS
– Next Generation Transit Survey
– near-infrared survey
– aim: Nepture-size planets
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Future – from space
• Continue to exploit Kepler and CoRoT data
– Kepler has thousands more candidates
– CoRoT has another ∼20 objects
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Future – from space
• Continue to exploit Kepler and CoRoT data
– Kepler has thousands more candidates
– CoRoT has another ∼20 objects
• CHEOPS is funded (will observe RV planets)
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Future – from space
• Continue to exploit Kepler and CoRoT data
– Kepler has thousands more candidates
– CoRoT has another ∼20 objects
• CHEOPS is funded (will observe RV planets)
• TESS will launch in 2017 and observe for 2 yr
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Future – from space
• Continue to exploit Kepler and CoRoT data
– Kepler has thousands more candidates
– CoRoT has another ∼20 objects
• CHEOPS is funded (will observe RV planets)
• TESS will launch in 2017 and observe for 2 yr
• GAIA is launched and data come soon
– Trigonometric distances to 109 stars
– Provide the additional constraint
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Future – from space
• Continue to exploit Kepler and CoRoT data
– Kepler has thousands more candidates
– CoRoT has another ∼20 objects
• CHEOPS is funded (will observe RV planets)
• TESS will launch in 2017 and observe for 2 yr
• GAIA is launched and data come soon
– Trigonometric distances to 109 stars
– Provide the additional constraint
• PLATO (2022-2024)
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Future follow-up
• High-stability spectrographs
– RV precision to 10 cm s−1:VLT/Espresso(Pepe et al., 2014AN....335....8P)
– RV precision to 2 cm s−1:E-ELT/Codex
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Future follow-up
• High-stability spectrographs
– RV precision to 10 cm s−1:VLT/Espresso(Pepe et al., 2014AN....335....8P)
– RV precision to 2 cm s−1:E-ELT/Codex
• JWST: infrared telescope
– MIRI: 5–28µm
– NIRSpec: 0.6–5µm
– occultation and transmissionspectroscopy
– atmospheres of habitabletransiting planets
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Summary
• Transiting planets are good
– only way to get mass, radius, density, surface gravity
– still need to understand host stars
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Summary
• Transiting planets are good
– only way to get mass, radius, density, surface gravity
– still need to understand host stars
• 1150 transiting planets known
– detection rate still increasing
– ground-based: interesting oddballs
– space-based: faint and less understood
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Summary
• Transiting planets are good
– only way to get mass, radius, density, surface gravity
– still need to understand host stars
• 1150 transiting planets known
– detection rate still increasing
– ground-based: interesting oddballs
– space-based: faint and less understood
• Now and soon:
– more planets
– Kepler and ground-based surveys
– ESPRESSO for follow-up
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Summary
• Transiting planets are good
– only way to get mass, radius, density, surface gravity
– still need to understand host stars
• 1150 transiting planets known
– detection rate still increasing
– ground-based: interesting oddballs
– space-based: faint and less understood
• Now and soon:
– more planets
– Kepler and ground-based surveys
– ESPRESSO for follow-up
• Future:
– TESS, CHEOPS, PLATO
– JWST and ELT RV machines
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