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A D- and N-15-Rich Micrometer-Sized Aggregate of Organic Matter in a Xenolithic Clast from the Zag Ordinary ChondriteThe nature and origin of extraterrestrial organic matter are still under debate despite the significant progress in the analyses and experimental approaches in this field over the last five decades. Xenolithic clasts are often found in a wide variety of meteorite groups, some of which contain exotic organic matter (OM). The Zag meteorite is a thermally-metamorphosed H ordinary chondrite. It contains a primitive xenolithic clast that has been proposed to have originated from Ceres, which was accreted to the Zag host asteroid after metamorphism. The cm-sized clast contains abundant large carbon-rich (mostly organic) grains or aggregates up to 20 microns. Such large OM grains are unique among astromaterials with respect to the size. Here we report organic and isotope analyses of a large (approx.10 microns) aggregate of solid OM in the Zag clast. The X-ray micro-spectroscopic technique revealed that the OM has sp2 bonded carbon with no other functional groups nor graphitic feature (1s-sigma exciton), and thus it is distinguished from most of the OM in carbonaceous meteorites. The apparent absence of functional groups in the OM suggests that it is composed of hydrocarbon networks with less heteroatoms, and therefore the OM aggregate is similar to hydrogenated amorphous carbon (HAC). The OM aggregate has high D/H and 15N/14N ratios, suggesting that it originated in a very cold environment such as the interstellar medium or outer region of the solar nebula, while the OM is embedded in carbonate-bearing matrix resulting from aqueous activities. Thus the high D/H ratio must have survived the extensive late-stage aqueous processing. It is not in the case for OM in carbonaceous chondrites of which the D/H ratio was reduced by the alteration via the D-H exchange of water. It indicates that both the OM precursors and the water had high D/H ratios, similar to the water in Enceladus. Our results support the idea that the clast originated from Ceres, or at least, a hydrovolcanically active body similar to Ceres, and further imply that Ceres originally formed in the outer Solar System and migrated to the main belt asteroid region as suggested by the "Grand tack" scenario.
Document ID
20180002204
Acquisition Source
Johnson Space Center
Document Type
Preprint (Draft being sent to journal)
Authors
Kebukawa, Yoko
(Yokohama National Univ. Japan)
Ito, Motoo
(Japan Marine Science and Technology Center Tokyo, Japan)
Zolensky, Michael E.
(NASA Johnson Space Center Houston, TX, United States)
Rahman, Zia
(Jacobs Technology, Inc. Houston, TX, United States)
Suga, Hiroki
(Hiroshima Univ. Japan)
Nakato, Aiko
(Kyoto Univ. Japan)
Chan, Queenie H. S.
(Open Univ. United Kingdom)
Fries, Marc
(NASA Johnson Space Center Houston, TX, United States)
Takeichi, Yasuo
(High Energy Accelerator Research Organization Tsukuba, Japan)
Takahashi, Yoshio
(Tokyo Univ. Hongo, Japan)
Mase, Kazuhiko
(High Energy Accelerator Research Organization Tsukuba, Japan)
Kobayashi, Kensei
(Yokohama National Univ. Japan)
Date Acquired
April 6, 2018
Publication Date
January 1, 2018
Subject Category
Space Sciences (General)
Report/Patent Number
JSC-E-DAA-TN53161
Funding Number(s)
CONTRACT_GRANT: NNJ13HA01C
Distribution Limits
Public
Copyright
Public Use Permitted.
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