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Evidence Suggesting that Oumuamua is the ~30 Myr-old product of a Molecular Cloud

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 Added by Cheng-Han Hsieh
 Publication date 2021
  fields Physics
and research's language is English




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The appearance of interstellar objects (ISOs) in the Solar System -- and specifically the arrival of 1I/Oumuamua -- points to a significant number density of free-floating bodies in the solar neighborhood. We review the details of Oumuamuas pre-encounter galactic orbit, which intersected the Solar System at very nearly its maximum vertical and radial excursion relative to the galactic plane. These kinematic features are strongly emblematic of nearby young stellar associations. We obtain an a-priori order-of-magnitude age estimate for Oumuamua by comparing its orbit to the orbits of 50,899 F-type stars drawn from Gaia DR2; a diffusion model then suggests a $sim$ 35 Myr dynamical age. We compare Oumuamuas orbit with the trajectories of individual nearby moving groups, confirming that its motion is fully consistent with membership in the Carina (CAR) moving group with an age around 30 Myr. We conduct Monte Carlo simulations that trace the orbits of test particles ejected from the stars in the Carina association. The simulations indicate that in order to uniformly populate the $sim10^6$ pc$^3$ volume occupied by CAR members with the inferred number density, $n=0.2,{rm AU}^{-3}$, of ISOs implied by Pan-STARRS detection of Oumuamua, the required ejection mass is $Msim 500$ $M_{rm Jup}$ per known star within the CAR association. This suggests that the Pan-STARRS observation is in significant tension with scenarios that posit Oumuamuas formation and ejection from a protostellar disk.



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