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Philippe Thébault Planet formation in binaries
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Planet formation in binaries why bother? a majority of solar-type stars in multiple systems >90 detected exoplanets in binaries Test bench for planet-formation scenarios
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Outline I Introduction - exoplanets and circumstellar discs in binaries - orbital stability II Planet formation: the different stages that can go wrong - disc truncation / grain condensation - embryo formation III Planetesimal accretion: the stage that goes really wrong IV Light at the end of the tunnel? V Circumbinary planets
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>12% of detected extrasolar planets in multiple systems But... (Raghavan et al., 2006, Roel et al., 2012) Exoplanets in Binaries ~2-3% ( 4-5 systems ) ”interesting” cases in close binaries with a b ≈20AU I
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(Raghavan et al., 2006) Gliese 86 HD 41004A γ Cephei (circumstellar) Exoplanets in Binaries I
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more massive planets on short-period orbits around close (<100AU) binaries Desidera&Barbieri, 2007 short period planets Statistical analysis Are planets-in-binaries different? Roel et al., 2012 Different formation process?? (Duchene, 2010) Roel et al., 2012 I
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Long-term stability analysis (Holman&Wiegert, 1999) (David et al., 2003) (Fatuzzo et al., 2006) I
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M 1 /M 2 =0.25 a b = 19 AU e b =0.41 Stability regions: a few examples a P = 2 AU e P =0.12 M 1 /M 2 =0.35 a b = 21 AU e b =0.42 a P = 0.11 AU e P =0.05 M 1 /M 2 =0.56 a b = 18 AU e b =0.40 a P = 2.6 AU e P =0.48 Cephei HD196885 Gl 86 I
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Statistical distribution of binary systems (Duquennoy&Mayor, 1991) a 0 ~30 AU ~50% binaries wide enough for stable Earths on S-type orbits ~10% close enough for stable Earths on P-type orbits I
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The « standard » model of planetary formation How could it be affected by binarity? Step by Step scenario: 1-protoplanetary disc formation √ 4-Planetesimal accretion √ 5-Embryo accretion √ 2-Grain condensation 3-formation of planetesimals x 6-Later evolution, resonances, migration √ II
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Grain condensation (Nelson, 2000) II
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Is there enough mass left to form planet(s)? Shorter viscous lifetime for discs in binaries Protoplanetary discs in binaries: theory tidal truncation of circumprimary & circumbinary discs Müller & Kley (2012) II Artymowicz & Lubow (1994)
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Protoplanetary discs in binaries: observations Most single stars have 3-5 Myr to form giant planets, but most (but not all!) tight binaries have <1 Myr Different formation process?? (Kraus et al., 2012) Discs in close binaries do have shorter lifetimes and are fainter
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Last stages of planet formation: embryos to planets (Guedes et al., 2008) Possible in almost the whole dynamically stable region (Barbieri et al. 2002, Quintana et al., 2002, 2007, Thebault et al. 2004, Haghighipour& Raymond 2007, Guedes et al., 2008,...) it takes a lot to prevent large embryos from accreting II
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very last stages of planet formation: planetary core migration (Kley & Nelson, 2008) “under the condition that protoplanetary cores can form …, it is possible to evolve and grow a core to form a planet with a final configuration similar to what is observed” II
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It doesn’t take much to stop planetesimal accretion V esc (1km) ~ 1-2m/s V ero (1km on 1km) ~ 10-20m/s dV runaway accretion V esc accretion (slowed down) V erosion erosion (no-accretion) 3 possible regimes : planetesimal accretion: Crucial parameter: impact velocity distribution III
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(e,a) evolution: purely gravitational case secular oscillations with phased orbits no increase untill orbit crossing occurs V (e 2 + i 2 ) 1/2 V Kep III
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M 2 =0.5M 1 e 2 =0.3 a 2 =20AU (Thebault et al., 2006)) III
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(e,a) evolution: with gas t final =5x10 4 yrs 1km<R<10km differential orbital phasing according to size III
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5km planetesimals 1km planetesimals Differential orbital alignement between objects of different sizes typical gas drag run dV increase (Thebault et al., 2006) III (Thebault et al., 2006))
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distribution at 1AU from α Cen A and at t=10 4 yrs high as soon as R 1 ≠R 2 (Thebault et al., 2008) III
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Benz&Asphaug, 1999 Critical fragmentation Energy (Q*) conflicting estimates III
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Accretion/Erosion behaviour V ero2 <dV erosion V ero1 <dV<V ero2 unsure V esc <dV<V ero1 perturbed accretion V esc <dV<V ero1 ”normal” accretion (Thebault et al., 2008) III at 1AU from α Cen A and at t=10 4 yrs
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Centauri B ”nominal case” erosion unsure perturbed accretion ”normal” accretion III (Thebault et al., 2009) HZ New Planet ! 0.04AU
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HD196885 III (Thebault, 2011) PARADOX? Planet At least 2 exoplanets are located in accretion-hostile regions
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“big” (10-50km) planetesimals ? at 1AU from the primary and at t=10 4 yrs IV
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large initial planetesimals? how realistic is a large « initial » planetesimals population? depends on planetesimal-formation scenario -> maybe possible if quick formation by instabilities (for ex. model of Johanssen 2007) but how do instabilities. proceed in the dynamically perturbed environment of a binary? ->more difficult if progressive sticking always have to pass through a km-sized phase in any case, it cannot be « normal » (runaway) accretion -> « type II » runaway? (Kortenkamp, 2001) IV
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evolving gas disc coupled hydro/N-body simulations always higher than in the axisymmetric gas disc case! Paardekooper, Thebault & Mellema, 2008 IV
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The role of the gas disc’s gravity dv are increased with respect to the gas-drag-only cases High dv even for equal-sized planetesimals Fragner, Nelson & Kley (2011) Inclined disc & circular binary IV
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outward migration after the formation of embryos Payne, Wyatt &Thébault (2009) IV
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different initial binary configuration? most stars are born in clusters early encounters and binary compaction/exchanges are possible: Initial and final (e,a) for binaries in a typical cluster (Malmberg et al., 2007) IV
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different initial orbit for the binary? Thebault et al., 2009 IV
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a slightly inclined binary might help (Xie & Zhou, 2009) IV Favours accretion-friendly impacts between equal-sized bodies
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a slightly inclined binary might help….but IV Xie & Zhou, 2009 …collision *rates* decrease dramatically
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“realistic” treatment of collisions Paardekooper & Leinhardt (2010) Collisions prevent the onset of size-phased orbits The production of collisional fragments favours growth by « dust » sweeping IV HZ
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Conclusions Gas drag works against planetesimal accretion In coplanar systems, in-situ planet formation is difficult in the HZ of binaries with ~20AU separation Outward migration of embryos by a/a ~ 0.25 is possible Moderate 1<i B <10 o helps, but slows down the accretion ~50% (?) chance that a 20AU binary was initially wider Fragment production and dust sweeping might help Different, binary-specific planet-formation scenario? Instabilities?
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Circumbinary planets: observations Most planets are close to the inner orbital stability limit V
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Circumbinary planets: modelling Paardekooper et al.(2012) no dust accretion with dust accretion even in the most favourable case, no in-situ accretion for the circumbinary planets …but inward type I or type II migration might solve the problem…and also explain the current location of the planets close to the inner stability limit V
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FIN
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