2005) If we limit ourselves to planets orbiting around the main

2005). If we limit ourselves to planets orbiting around the main sequence stars then among planets with the very small mass we can mention GJ581 e with a mass

of about 1.95 m  ⊕  (Mayor et al. 2009a). The task of identifying the most massive planet is much more difficult, because in this case we encounter the problem of distinguishing planets from brown dwarfs. So let us mentioned just the most massive non-stellar object, which is CD-352722b (31 m J , Wahhaj 2011). OSI-027 Extrasolar planets are observed very close to their host stars, for example in a distance of 0.014 AU (GJ 1214 b, Charbonneau et al. 2009) or 0.006 AU (Kepler 55b, Charpinet et al. 2011), but also far away from the central stars www.selleckchem.com/products/anlotinib-al3818.html (hundreds of AU). The most distant planet in the system HR 8799 is located at the distance of 68 AU from its host star (Marois et al. 2008). The orbits of Jovian-like planets have eccentricities e, typically in the range from zero till 0.5, while Neptune-like and super-Earths move on orbits with e < 0.2 (Wright 2010). The biggest known eccentricity, e = 0.97, belongs to the planet HD 20782b which has a mass of 1.9 m J (O’Toole et al. 2009). Besides planets orbiting stars there are also planetary objects,

which are not bounded gravitationally around any star, we call the latter free floating planets. One example of free floating planets is that of ρ Oph 4450, which has been discovered by direct imaging (Marsh et al. 2010). Such a diversity of objects is a big challenge for the theory of planetary system formation and evolution. The most common planets detected so far orbiting stars similar to our Sun are gas giants with a mass of the order of that of Jupiter. They move on their orbits very close to their host stars, at a distance of 1 AU or

smaller. A typical (as for today) planetary system is then very different NADPH-cytochrome-c2 reductase from our Solar System. The existence of gas giants so close to the central stars poses severe difficulties in explaining how they were formed if they were really originated where they are located now. These difficulties at least partially have been removed thanks to the theory of the orbital migration developed in details at the end of the seventies of the last century (Goldreich and Tremaine 1979; Lin and Papaloizou 1986). The application of this theory allows the gas giants to form far away from the star, where the conditions are favorable for their formation and then to “walk into” the Caspase Inhibitor VI in vivo region where they are observed. The planetary migration should be a common phenomenon occurring in the early stages of the planetary system evolution. In the study of resonant configurations, there is a particular region of interest around a gas giant, namely a zone extended from 0.6 till 1.7 a J , where a J is the gas giant distance from the host star. The first order commensurabilities are located in this region.

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