A Possible Stellar Metallic Enhancement in Post-T Tauri Stars by a Planetesimal Bombardment

The photospheres of stars hosting planets have larger metallicity than stars lacking planets. In the present work we study the possibility of an earlier metal enrichment of the photospheres by means of impacting planetesimals during the first 20-30Myr. Here we explore this contamination process by s...

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Bibliographic Details
Published in:arXiv.org 2007-04
Main Authors: Winter, O C, de la Reza, R, Domingos, R C, Boldrin, L A G, Chavero, C
Format: Article
Language:English
Subjects:
Bombardment
Computer simulation
Dependence
Eccentricity
Extrasolar planets
Gas giant planets
Jupiter
Metallicity
Migration
Orbital resonances (celestial mechanics)
Planet formation
Solar corona
Stars
T Tauri stars
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Summary:The photospheres of stars hosting planets have larger metallicity than stars lacking planets. In the present work we study the possibility of an earlier metal enrichment of the photospheres by means of impacting planetesimals during the first 20-30Myr. Here we explore this contamination process by simulating the interactions of an inward migrating planet with a disc of planetesimal interior to its orbit. The results show the percentage of planetesimals that fall on the star. We identified the dependence of the planet's eccentricity (\(e_p\)) and time scale of migration (\(\tau\)) on the rate of infalling planetesimals. For very fast migrations (\(\tau=10^2\)yr and \(\tau=10^3\)yr) there is no capture in mean motion resonances, independently of the value of \(e_p\). Then, due to the planet's migration the planetesimals suffer close approaches with the planet and more than 80% of them are ejected from the system. For slow migrations (\(\tau=10^5\)yr and \(\tau=10^6\)yr) the percentage of collisions with the planet decrease with the increase of the planet's eccentricity. For \(e_p=0\) and \(e_p=0.1\) most of the planetesimals were captured in the 2:1 resonance and more than 65% of them collided with the star. Whereas migration of a Jupiter mass planet to very short pericentric distances requires unrealistic high disc masses, these requirements are much smaller for smaller migrating planets. Our simulations for a slowly migrating 0.1 \(M_{\rm Jupiter}\) planet, even demanding a possible primitive disc three times more massive than a primitive solar nebula, produces maximum [Fe/H] enrichments of the order of 0.18 dex. These calculations open possibilities to explain hot Jupiters exoplanets metallicities.
ISSN:2331-8422
DOI:10.48550/arxiv.0704.2997