A PROTOSOLAR NEBULA ORIGIN FOR THE ICES AGGLOMERATED BY COMET 67P/CHURYUMOV–GERASIMENKO

The nature of the icy material accreted by comets during their formation in the outer regions of the protosolar nebula (PSN) is a major open question in planetary science. Some scenarios of comet formation predict that these bodies agglomerated from crystalline ices condensed in the PSN. Concurrently, alternative scenarios suggest that comets accreted amorphous ice originating from the interstellar cloud or from the very distant regions of the PSN. On the basis of existing laboratory and modeling data, we find that the N2/CO and Ar/CO ratios measured in the coma of the Jupiter-family comet 67P/Churyumov–Gerasimenko by the Rosetta Orbiter Spectrometer for Ion and Neutral Analysis instrument on board the European Space Agency’s Rosetta spacecraft match those predicted for gases trapped in clathrates. If these measurements are representative of the bulk N2/CO and Ar/CO ratios in 67P/Churyumov–Gerasimenko, it implies that the ices accreted by the comet formed in the nebula and do not originate from the interstellar medium, supporting the idea that the building blocks of outer solar system bodies have been formed from clathrates and possibly from pure crystalline ices. Moreover, because 67P/Churyumov–Gerasimenko is impoverished in Ar and N2, the volatile enrichments observed in Jupiter’s atmosphere cannot be explained solely via the accretion of building blocks with similar compositions and require an additional delivery source. A potential source may be the accretion of gas from the nebula that has been progressively enriched in heavy elements due to photoevaporation.

[1]  J. Berthelier,et al.  Composition-dependent outgassing of comet 67P/Churyumov-Gerasimenko from ROSINA/DFMS - Implications for nucleus heterogeneity? , 2015 .

[2]  N. Thomas,et al.  PITS FORMATION FROM VOLATILE OUTGASSING ON 67P/CHURYUMOV–GERASIMENKO , 2015, 1510.07671.

[3]  T. Owen,et al.  Detection of argon in the coma of comet 67P/Churyumov-Gerasimenko , 2015, Science Advances.

[4]  T. Owen,et al.  Molecular nitrogen in comet 67P/Churyumov-Gerasimenko indicates a low formation temperature , 2015, Science.

[5]  J. Simon,et al.  A ∼32–70 K FORMATION TEMPERATURE RANGE FOR THE ICE GRAINS AGGLOMERATED BY COMET 67 P/CHURYUMOV–GERASIMENKO , 2015, 1504.01678.

[6]  E. Kührt,et al.  Time variability and heterogeneity in the coma of 67P/Churyumov-Gerasimenko , 2015, Science.

[7]  E. Neefs,et al.  67P/Churyumov-Gerasimenko, a Jupiter family comet with a high D/H ratio , 2015, Science.

[8]  J. Lunine,et al.  NEW INSIGHTS ON SATURN'S FORMATION FROM ITS NITROGEN ISOTOPIC COMPOSITION , 2014, 1410.5408.

[9]  T. Germann,et al.  Encapsulation kinetics and dynamics of carbon monoxide in clathrate hydrate , 2014, Nature Communications.

[10]  F. Ciesla THE PHASES OF WATER ICE IN THE SOLAR NEBULA , 2014, 1402.5333.

[11]  A. Bar-Nun,et al.  CO2 as the driving force of comet Hartley 2’s activity—An experimental study , 2013 .

[12]  A. Morbidelli,et al.  Oort cloud and Scattered Disc formation during a late dynamical instability in the Solar System , 2012, 1303.3098.

[13]  Nikku Madhusudhan,et al.  NEBULAR WATER DEPLETION AS THE CAUSE OF JUPITER'S LOW OXYGEN ABUNDANCE , 2012, 1204.3887.

[14]  B. Schmitt,et al.  Pressure dependent trace gas trapping in amorphous water ice at 77 K: Implications for determining conditions of comet formation , 2012 .

[15]  U. Michigan,et al.  The chemical history of molecules in circumstellar disks - II. Gas-phase species , 2011, 1109.1741.

[16]  J. Petit,et al.  ON THE FORMATION LOCATION OF URANUS AND NEPTUNE AS CONSTRAINED BY DYNAMICAL AND CHEMICAL MODELS OF COMETS , 2011, 1104.4977.

[17]  J. Lunine,et al.  Volatile inventories in clathrate hydrates formed in the primordial nebula. , 2010, Faraday discussions.

[18]  H. Gail,et al.  Abundances of the elements in the solar system , 2009, 0901.1149.

[19]  J. Lunine,et al.  CLATHRATION OF VOLATILES IN THE SOLAR NEBULA AND IMPLICATIONS FOR THE ORIGIN OF TITAN'S ATMOSPHERE , 2008, 0810.0308.

[20]  T. Owen,et al.  Trapping of N2, CO and Ar in amorphous ice—Application to comets , 2007 .

[21]  L. Duvet,et al.  Rosina – Rosetta Orbiter Spectrometer for Ion and Neutral Analysis , 2007 .

[22]  T. Guillot,et al.  The composition of Jupiter: sign of a (relatively) late formation in a chemically evolved protosolar disc , 2006, astro-ph/0601043.

[23]  Ross Anderson,et al.  Carbon monoxide clathrate hydrates: Equilibrium data and thermodynamic modeling , 2005 .

[24]  T. Owen,et al.  Gas trapping in water ice at very low deposition rates and implications for comets , 2003 .

[25]  J. Lunine,et al.  An interpretation of the nitrogen deficiency in comets , 2003 .

[26]  J. Lunine,et al.  Enrichments in Volatiles in Jupiter: A New Interpretation of the Galileo Measurements , 2001 .

[27]  B. Dubrulle,et al.  Constraints on the Formation of Comets from D/H Ratios Measured in H2O and HCN , 2000 .

[28]  T. Owen,et al.  An experimental study of the isotopic enrichment in Ar, Kr, and Xe when trapped in water ice. , 1999, Icarus.

[29]  P. Cassen,et al.  Thermal Processing of Interstellar Dust Grains in the Primitive Solar Environment , 1997 .

[30]  A. Bar-Nun,et al.  Trapping of gas mixtures by amorphous water ice. , 1988, Physical review. B, Condensed matter.

[31]  A. Bar-Nun,et al.  Amorphous water ice and its ability to trap gases. , 1987, Physical review. B, Condensed matter.

[32]  J. Lunine,et al.  Thermodynamics of clathrate hydrate at low and high pressures with application to the outer solar system , 1985 .

[33]  J. S. Lewis,et al.  Kinetic inhibition of CO and N2 reduction in the solar nebula , 1980 .

[34]  D. Gautier,et al.  Formation and Composition of Planetesimals , 2005 .

[35]  A. Bar-Nun,et al.  First experimental studies of large samples of gas-laden amorphous “cometary” ices , 2003 .

[36]  J. M. Prausnitz,et al.  Dissociation Pressures of Gas Hydrates Formed by Gas Mixtures , 1972 .