Tidal Downsizing model – III. Planets from sub-Earths to brown dwarfs: structure and metallicity preferences

Tidal Downsizing model – III. Planets from sub-Earths to brown dwarfs: structure and metallicity preferences

We present population synthesis calculations of the Tidal Downsizing (TD) hypothesis for planet formation. Our models address the following observations: (i) most abundant planets being super-Earths; (ii) cores more massive than ∼5–15 M⊕ are enveloped by massive atmospheres; (iii) the frequency of o...

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Veröffentlicht in:Monthly notices of the Royal Astronomical Society 2015-09, Vol.452 (2), p.1654-1676
Hauptverfasser: Nayakshin, Sergei, Fletcher, Mark
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Sprache:eng
Schlagworte:
Accretion
Accretion disks
Brown dwarfs
Correlation
Downsizing
Extrasolar planets
Mathematical models
Metallicity
Planet formation
Planetology
Planets
Star & galaxy formation
Stars
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creator Nayakshin, Sergei
Fletcher, Mark
description We present population synthesis calculations of the Tidal Downsizing (TD) hypothesis for planet formation. Our models address the following observations: (i) most abundant planets being super-Earths; (ii) cores more massive than ∼5–15 M⊕ are enveloped by massive atmospheres; (iii) the frequency of occurrence of close-in gas-giant planets correlates strongly with metallicity of the host star; (iv) no such correlation is found for sub-Neptune planets; (v) presence of massive cores in giant planets; (vi) gas-giant planets are overabundant in metals compared to their host stars; (vii) this overabundance decreases with planet's mass; (viii) a deep valley in the planet mass function between masses of ∼10–20 M⊕ and ∼100 M⊕. A number of observational predictions distinguish the model from Core Accretion: (a) composition of the massive cores is always dominated by rocks not ices; (b) the core mass function is smooth with no minimum at ∼3 M⊕ and has no ice-dominated cores; (c) gas giants beyond 10 au are insensitive to the host-star metallicity; (d) objects more massive than ∼10 M J do not correlate or even anticorrelate with metallicity. The latter prediction is consistent with observations of low-mass stellar companions. TD can also explain formation of planets in close binary systems. TD model is a viable alternative to the Core Accretion scenario in explaining many features of the observed population of exoplanets.
doi_str_mv 10.1093/mnras/stv1354
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A number of observational predictions distinguish the model from Core Accretion: (a) composition of the massive cores is always dominated by rocks not ices; (b) the core mass function is smooth with no minimum at ∼3 M⊕ and has no ice-dominated cores; (c) gas giants beyond 10 au are insensitive to the host-star metallicity; (d) objects more massive than ∼10 M J do not correlate or even anticorrelate with metallicity. The latter prediction is consistent with observations of low-mass stellar companions. TD can also explain formation of planets in close binary systems. 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Planets from sub-Earths to brown dwarfs: structure and metallicity preferences</title><title>Monthly notices of the Royal Astronomical Society</title><description>We present population synthesis calculations of the Tidal Downsizing (TD) hypothesis for planet formation. Our models address the following observations: (i) most abundant planets being super-Earths; (ii) cores more massive than ∼5–15 M⊕ are enveloped by massive atmospheres; (iii) the frequency of occurrence of close-in gas-giant planets correlates strongly with metallicity of the host star; (iv) no such correlation is found for sub-Neptune planets; (v) presence of massive cores in giant planets; (vi) gas-giant planets are overabundant in metals compared to their host stars; (vii) this overabundance decreases with planet's mass; (viii) a deep valley in the planet mass function between masses of ∼10–20 M⊕ and ∼100 M⊕. 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Planets from sub-Earths to brown dwarfs: structure and metallicity preferences</atitle><jtitle>Monthly notices of the Royal Astronomical Society</jtitle><date>2015-09-11</date><risdate>2015</risdate><volume>452</volume><issue>2</issue><spage>1654</spage><epage>1676</epage><pages>1654-1676</pages><issn>0035-8711</issn><eissn>1365-2966</eissn><abstract>We present population synthesis calculations of the Tidal Downsizing (TD) hypothesis for planet formation. 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subjects Accretion
Accretion disks
Brown dwarfs
Correlation
Downsizing
Extrasolar planets
Mathematical models
Metallicity
Planet formation
Planetology
Planets
Star & galaxy formation
Stars
title Tidal Downsizing model – III. Planets from sub-Earths to brown dwarfs: structure and metallicity preferences
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