Detection of Extrasolar Giant Planets Hwihyun Kim 03/30/06.
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Transcript of Detection of Extrasolar Giant Planets Hwihyun Kim 03/30/06.
Detection of Extrasolar Giant Planets
Hwihyun Kim03/30/06
PAPER
• G. W. Marcy & R. P. Butler, “Detection of Extrasolar Giant Planets”, ARAA, 1998, 36:57-97
HISTORY OF DETECTION
• 4th century : Aristotle and Epicurus argued about the uniqueness of the Earth
• Late 1500s : Copernicus(con), G. Bruno(pro)
• Early-1900s : – some “spiral nebulae” such as M51 misinterpreted as
planetary systems– Jeans-Jeffreys’ model for planet formation – Aitken(1938) : direct detection or by the wobble
HISTORY OF DETECTION
• Wolszczan & Frail (1992) : 1st planetary system, PSR1257+12 (post-SN recapture of material) by pulsar-timing method
• Mayor & Queloz (1995) : 51 Pegasi by Doppler periodicity
• Butler & Marcy (1996) : 1st detections of Jupiter-mass planets to solar-type star, 47 UMa and 70 Vir
• 2000s : HST-NICMOS, Spitzer, Kepler Space Mission(2007 ?), Space Interferometry Mission(SIM), Terrestrial Planet Finder(TPF) and so on....
DETECTION TECHNIQUES
• Direct Detections
• Astrometric Detections
• Photometric Technique
• Doppler Technique
• Pulsar Timing
• Gravitational Microlensing
DIRECT DETECTIONS
• Direct Imaging – Small fluxes from the planets– Competing wings of the stellar PSF
• Solar-type star with MJ-planet at 5AU (Benchmark model)– Visible : ~10-9 (Vs = 5 and Vp = 27, 0.5”)– IR : improved to ~10-4 but low-resolution(>1”)
• Noise in PSF wings : seeing, microroughness of the mirror, and diffraction
DIRECT DETECTIONS
• Minimum aperture D (diffraction alone)
• Remedy– Adaptive optics, Dark-speckle camera(JWST ?)– Ground-based interferometry, Keck, VLT, Spitzer....
50.4
1 10
D:aperture, λ:wavelength used, d:distance,
r:orbital separation
d AUD meters
pc r
ASTROMETRIC DETECTIONS
• Stellar (proper) motion by its companion– Determine Mp and i of a planet– Detect sub-MJ planets with future precision below 0.1 milliarcsec (ma
s)– Confirm planets detected by other means
• Angular wobble – Proportional to Mp and r– Inversely proportional to d
• Benchmark model : 0.5 mas
• Palomar 5-m (~250 μas, 1997), Keck (20 μas), & SIM (4 μas)
PHOTOMETRIC TECHNIQUE
• Transit method : reduction in light– aligned from astronomers’ vantage
point
– 1% dimming by the Jupiter size planet
– Probability :
*
*
tan
i:inclination, a:semi-major axis, R :stellar radius
aiR
( ' 90 ) cos 'P i i i
PHOTOMETRIC TECHNIQUE
• Marcy & Butler(1997) : 0.19% of solar-type star exhibit transits
• Determination of – existence rate– occurrence rate – Planet radius
DOPPLER TECHNIQUE
• Our Sun– wobbles around the barycenter with ~13m/s b
y Jupiter(12.5 m/s) and Saturn(2.7m/s)
• Semi-amplitude K of the stellar radial velocity 1/3
2 /3 2
2 32
*
sin2 1
( * ) 1
4 (Kepler's third law)
( )
p
p
p
m iGK
p M m e
ap
G M m
DOPPLER TECHNIQUE
• Detectability of companions by the reflex velocity
• Intrinsic velocity scatter(σ) vs. rotational period(P) for F( ), G(∆ ⊙) and K(■) dwarfs (Saar et al, 1997)
OBSERVATIONS OF EXTRASOLAR PLANETS
• Walker et al (1995) : 21 dwarfs for 12 yrs with 13m/s
• Mayor & Queloz (1995) : 140 MS stars for 3 yrs
• Cochran & Hatzes (1994) : 33 stars for 10 yrs
• Marcy & Butler (1997) : 107 FGKM dwarfs with ~10m/s (8yrs) and 3m/s (4yrs)
DISTRIBUTION OF PLANETARY MASSES
• Histogram of M sini for all companions known around solar-type stars
• Tallest peak is at the lowest, least detectable masses(0-10 MJ)
47 Ursae Majoris• By Butler & Marcy (1996) with Doppler
measurement
• P = 3.0 yrs, e = 0.09 ± 0.04, a = 2.1 ± 0.1 AU and companion mass = (2.4 ± 0.1)/sini
55 Cancri and ρ Corona Borealis
• Mp ~ 1.0 MJ/sini (true masses < 3MJ)
• Orbital radii : 0.11 AU (55 Cnc) and 0.24 AU (ρ CrB) placing them inward of the ice-condensation point (~3AU)
• Low eccentricities (e= 0.04 and 0.11) – ρ CrB : too large orbit for tidal effects to cause low-e– 55 Cnc : tidal circulation and period of 14.7 days
• a) 55 Cnc
• b) ρ CrB by Noyes et al (1997)
• Both appear to have MJ-companions in nearly circular orbits.
70 Vir & 16 Cygni B : non-sinusoidal velocities
• Very eccentric Keplerian curves – e = 0.4 (70 Vir) and 0.687 (16 Cygni B)– Well fit by a simple Keplerian model
70 Vir ( Mp = 6.7 MJ/sini ) 16 Cygni - Lick( ) & McDonald(x)∆
- Mp = 1.67 ± 0.1 MJ/sini
GIANTS PLANETS ORBITING WITHIN 0.1AU
• MJ-companions with the orbital radii <0.1 AU
• Proximity to the star enhances the detectability (Fig. 1)
• 51 Peg : active corona and high X-ray flux
• Tau Boo : higher mass companion (3.7 MJ/sini )
• Upsilon And : short-term scatter (25m/s) by the rapid rotation of the star
SUMMARY
• 8 extrasolar planet candidates have been identified by Keplerian Doppler shifts(1998).
• Masses are between 0.5-7 MJ and semi-major axes are less than 2.1 AU.
• Detections imply that ~6% of solar-type stars have giant planets within 2 AU.