Linking the primordial composition of planet building disks to the present-day composition of rocky exoplanets

Adibekyan, V.; Deal, M.; Dorn, C.; Dittrich, I.; Soares, B. M. T. B.; Sousa, S. G.; Santos, N. C.; Bitsch, B.; Mordasini, C.; Barros, S. C. C.; Bossini, D.; Campante, T. L.; Delgado Mena, E.; Demangeon, O. D. S.; Figueira, P.; Moedas, N.; Martirosyan, Zh.; Israelian, G.; Hakobyan, A. A.

doi:10.1051/0004-6361/202452193

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2024

DOI: 10.1051/0004-6361/202452193

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Linking the primordial composition of planet building disks to the present-day composition of rocky exoplanets

V. Adibekyan,

M. Deal,

C. Dorn

et al.

Abstract: The composition of rocky planets is strongly driven by the primordial materials in the protoplanetary disk, which can be inferred from the abundances of the host star. Understanding this compositional link is crucial for characterizing exoplanets. We aim to investigate the relationship between the compositions of low-mass planets and their host stars. We determined the primordial compositions of host stars using high-precision present-day stellar abundances and stellar evolutionary models. These primordial abu… Show more

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On the formation of super-Jupiters: core accretion or gravitational instability?

Nguyen,

Adibekyan

2024

Astrophys Space Sci

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The Core Accretion model is widely accepted as the primary mechanism for forming planets up to a few Jupiter masses. However, the formation of super-massive planets remains a subject of debate, as their formation via the Core Accretion model requires super-solar metallicities. Assuming stellar atmospheric abundances reflect the composition of protoplanetary disks, and that disk mass scales linearly with stellar mass, we calculated the total amount of metals in planet-building materials that could contribute to the formation of massive planets. In this work, we studied a sample of 172 Jupiter-mass planets and 93 planets with masses exceeding 4 $M_{\jupiter}$ M ♃ . Our results consistently demonstrate that planets with masses above 4 $M_{\jupiter}$ M ♃ form in disks with at least as much metal content as those hosting planets with masses between 1 and 4 $M_{\jupiter}$ M ♃ , often with slightly higher metallicity, typically exceeding that of the proto-solar disk. We interpret this as strong evidence that the formation of very massive Jupiters is feasible through Core Accretion and encourage planet formation modelers to test our observational conclusions.

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On the formation of super-Jupiters: core accretion or gravitational instability?

Nguyen,

Adibekyan

2024

Astrophys Space Sci

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Linking the primordial composition of planet building disks to the present-day composition of rocky exoplanets

Cited by 1 publication

References 71 publications

On the formation of super-Jupiters: core accretion or gravitational instability?

On the formation of super-Jupiters: core accretion or gravitational instability?

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