The peculiar properties of the Solar System Alessandro Morbidelli CNRS/Observatoire de la Cote d'Azur, Nice, France.

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Presentation transcript:

The peculiar properties of the Solar System Alessandro Morbidelli CNRS/Observatoire de la Cote d'Azur, Nice, France.

Radial velocity (Mayor et al., 2011) and transit surveys (Howard et al., 2012; Petigura et al., 2013; Fressin et al., 2013) suggest that many (most?) solar-type stars have close-in Super-Earths / Neptune-like (SEN) planets The Solar System is atypical in that our Neptune-like planets are not close-in, but they are beyond Jupiter & Saturn Batygin and Laughlin, 2015

Giant planet orbital distribution Our Solar System have giant planets, like probably only ~15% of the other stars, but our giant planets have orbits very different from the extrasolar ones discovered so far.

The formation of giant planet cores has remained a mystery for long time, but now we have a new theory that seems to work (Lambrechts et Johansen, 2012, 2014; Johansen et al., 2015) But why giant planet cores formed only in the outer part of the disk?

IDEA r snowline Icy particles flux Silicate particles flux D ~ cm-dm D < mm Morbidelli et al., Icarus in press Core beyond the snowline Embryo within the snowline

r snowline

dM/dt=1x10 -8 M S /y dM/dt=5x10 -8 M S /y dM/dt=5x10 -9 M S /y Bitsch et al., 2013 All SENs should migrate from the outer disk to the inner disk, eventually. Outward migration regions work only for a limited mass-range of SENs and disappear as the disk evolves to a smaller accretion rate

Izidoro et al., 2014 The slow inward migration of SENs is a hazard for the formation of true terrestrial planets

Izidoro et al., 2014 The slow inward migration of SENs is a hazard for the formation of true terrestrial planets

If the innermost SEN becomes a giant planet, results are very different r r What happens when a SEN approaches a giant planet? Will it go through its orbit and continue its migration towards the star or will it be blocked? A SEN migrates inwards faster than a giant planet In some cases, giant planets can migrate inwards, while SENs migrate inwards Thus, SENs tend to approach the giant planet(s)

If the innermost SEN becomes a giant planet, results are very different MMSN disk MMSN MMSN disk with inner cavity Only a fraction of SEN systems initially located beyond a Jupiter- mass planet have a SEN jumping across the Jovian orbit into the inner disk Statistics made on 100 runs for each configuration (Number of SENs, their total mass) Izidoro et al., 2015, ApJ 800L, 22I

Giant planets are extremely effective in retaining Super-Earths behind them (Izidoro, Raymond and Morbidelli, ApJ 800L, 22I) Izidoro et al., 2015, ApJ 800L, 22I

Giant planets are extremely effective in retaining Super-Earths behind them (Izidoro, Raymond and Morbidelli, ApJ 800L, 22I) Izidoro et al., 2015, ApJ 800L, 22I

IMPLICATIONS FOR THE SOLAR SYSTEM Uranus and Neptune did not migrate into the inner Solar System because they have been retained by Jupiter and Saturn The large obliquities of Uranus and Neptune indicate that these planets should have experienced giant collisions and this suggests they assembled from several merging embryos. The dynamical barrier offered by Jupiter and Saturn offers a framework for this to happen Izidoro et al., submitted Jakubik et al., 2012

IMPLICATION FOR EXTRASOLAR SYSTEMS If close-in SENs originated by inward migration and if it is the innermost SEN that is the most likely to become a giant planet then we expect an anti-correlation between close-in SENs and giant planets. Systems of close-in SENs no giant planets A single close-in SEN a giant planet further out No close-in SENs a giant planet further out Of course, we expect this correlation not to be 100% true. Some close-in SENs might have formed in-situ, in other cases the giant planet might not have formed from the innermost SEN. The reliability of this correlation (to be observationally determined) will tell us how often the ifs are valid and therefore it will allow us to infer information on the origin of close-in SENs and formation of giant planets. r r r

Conclusions (1/2) Giant planets are the key! The formation of big icy planets (SENs) beyond the snowline should be generic… …as well as their migration into the inner system If the innermost SEN becomes a gas-giant planet it can offer a dynamical barrier against the migration of the other SENs into the inner disk The migration of SENs is confined by the migration of the gas-giant planet In most extrasolar systems, gas-giant planets migrated down to ~ 1-2 AU In our system, the mass ratio between Saturn and Jupiter promoted outward migration (distant giant planets). The large eccentricities of the extrasolar gas-giant planets are believed to be due the consequence of past orbital instability The Solar System passed through a giant planet instability as well, but a weak one because our giant planets are relatively low-mass and in addition Jupiter and Saturn, by chance, did not encounter with each other.

Final orbit of Jupiter if encounters with Saturn occur Final orbit of Jupiter if Jupiter-Saturn encounters do not occur.

Conclusions (2/2) The Three Chances of our Solar System: 1.The innermost core became a giant planet 2.The mass ratio between Jupiter and Saturn prevented these planets to come to close to 1 AU 3.The giant planet instability was mild because Jupiter and Saturn avoided mutual encounters All this suggests that the Solar System must be very a-typical