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Ice-coated Pebble Drift as a Possible Explanation for Peculiar Cometary CO/H<sub>2</sub>O Ratios

Ellen M. Price, L. Ilsedore Cleeves, Dennis Bodewits, Karin I. Öberg

2021The Astrophysical Journal17 citationsDOIOpen Access PDF

Abstract

Abstract To date, at least three comets—2I/Borisov, C/2016 R2 (PanSTARRS), and C/2009 P1 (Garradd)—have been observed to have unusually high CO concentrations compared to water. We attempt to explain these observations by modeling the effect of drifting solid (ice and dust) material on the ice compositions in protoplanetary disks. We find that, independent of the exact disk model parameters, we always obtain a region of enhanced ice-phase CO/H 2 O that spreads out in radius over time. The inner edge of this feature coincides with the CO snowline. Almost every model achieves at least CO/H 2 O of unity, and one model reaches a CO/H 2 O ratio &gt;10. After running our simulations for 1 Myr, an average of 40% of the disk ice mass contains more CO than H 2 O ice. In light of this, a population of CO-ice-enhanced planetesimals are likely to generally form in the outer regions of disks, and we speculate that the aforementioned CO-rich comets may be more common, both in our own solar system and in extrasolar systems, than previously expected.

Topics & Concepts

PhysicsPlanetesimalAstrophysicsRADIUSPebblePopulationSolar SystemProtoplanetary diskProtoplanetExoplanetPlanetPlanetary systemAstronomyWater iceEnhanced Data Rates for GSM EvolutionCometMass ratioTerrestrial planetLuminosityFormation and evolution of the Solar SystemFeature (linguistics)AstrobiologySolar radiusAstrophysics and Star Formation StudiesAstro and Planetary ScienceStellar, planetary, and galactic studies
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