NanoSIMS C-, N-, and O-isotopic mapping of matrix in CO3.0 chondrite Dominion Range (DOM) 08006 revealed it to have in its matrix the highest abundance of presolar O-rich grains (257 +76/-96 ppm, 2σ) of any meteorite. It also has a matrix abundance of presolar SiC of 35 (+25/-17, 2σ) ppm, similar to that seen across primitive chondrite classes. This provides additional support to bulk isotopic and petrologic evidence that DOM 08006 is the most primitive known CO meteorite. Transmission electron microscopy of five presolar silicate grains revealed one to have a composite mineralogy similar to larger amoeboid olivine aggregates and consistent with equilibrium condensation, two non-stoichiometric amorphous grains and two olivine grains, though one is identified as such solely based on its composition. We also found insoluble organic matter (IOM) to be present primarily as sub-micron inclusions with ranges of C- and N-isotopic anomalies similar to those seen in primitive CR chondrites and interplanetary dust particles. In contrast to other primitive extraterrestrial materials, H isotopic imaging showed normal and homogeneous D/H. Most likely, DOM 08006 and other CO chondrites accreted a similar complement of primitive and isotopically anomalous organic matter to that found in other chondrite classes and IDPs, but the very limited amount of thermal metamorphism experienced by DOM 08006 has caused loss of D-rich organic moieties, while not substantially affecting either the molecular carriers of C and N anomalies or most inorganic phases in the meteorite. One C-rich grain that was highly depleted in 13C and 15N was identified; we propose it originated in the Sun's parental molecular cloud.
NanoSIMS C-, n class="Chemical">N-, and O-isotopic mapping of matrix in CO3.0 chondrite Dominion Range (DOM) 08006 revealed it to have in its matrix the highest abundance of presolar O-rich grains (257 +76/-96 ppm, 2σ) of any meteorite. It also has a matrix abundance of presolar SiC of 35 (+25/-17, 2σ) ppm, similar to that seen across primitive chondrite classes. This provides additional support to bulk isotopic and petrologic evidence that DOM 08006 is the most primitive known CO meteorite. Transmission electron microscopy of five presolar silicate grains revealed one to have a composite mineralogy similar to larger amoeboid olivine aggregates and consistent with equilibrium condensation, two non-stoichiometric amorphous grains and two olivine grains, though one is identified as such solely based on its composition. We also found insoluble organic matter (IOM) to be present primarily as sub-micron inclusions with ranges of C- and N-isotopic anomalies similar to those seen in primitive CR chondrites and interplanetary dust particles. In contrast to other primitive extraterrestrial materials, H isotopic imaging showed normal and homogeneous D/H. Most likely, DOM 08006 and other CO chondrites accreted a similar complement of primitive and isotopically anomalous organic matter to that found in other chondrite classes and IDPs, but the very limited amount of thermal metamorphism experienced by DOM 08006 has caused loss of D-rich organic moieties, while not substantially affecting either the molecular carriers of C and N anomalies or most inorganic phases in the meteorite. One C-rich grain that was highly depleted in 13C and 15N was identified; we propose it originated in the Sun's parental molecular cloud.
Authors: Kevin D McKeegan; Jerome Aléon; John Bradley; Donald Brownlee; Henner Busemann; Anna Butterworth; Marc Chaussidon; Stewart Fallon; Christine Floss; Jamie Gilmour; Matthieu Gounelle; Giles Graham; Yunbin Guan; Philipp R Heck; Peter Hoppe; Ian D Hutcheon; Joachim Huth; Hope Ishii; Motoo Ito; Stein B Jacobsen; Anton Kearsley; Laurie A Leshin; Ming-Chang Liu; Ian Lyon; Kuljeet Marhas; Bernard Marty; Graciela Matrajt; Anders Meibom; Scott Messenger; Smail Mostefaoui; Sujoy Mukhopadhyay; Keiko Nakamura-Messenger; Larry Nittler; Russ Palma; Robert O Pepin; Dimitri A Papanastassiou; François Robert; Dennis Schlutter; Christopher J Snead; Frank J Stadermann; Rhonda Stroud; Peter Tsou; Andrew Westphal; Edward D Young; Karen Ziegler; Laurent Zimmermann; Ernst Zinner Journal: Science Date: 2006-12-15 Impact factor: 47.728
Authors: Christopher D K Herd; Alexandra Blinova; Danielle N Simkus; Yongsong Huang; Rafael Tarozo; Conel M O'D Alexander; Frank Gyngard; Larry R Nittler; George D Cody; Marilyn L Fogel; Yoko Kebukawa; A L David Kilcoyne; Robert W Hilts; Greg F Slater; Daniel P Glavin; Jason P Dworkin; Michael P Callahan; Jamie E Elsila; Bradley T De Gregorio; Rhonda M Stroud Journal: Science Date: 2011-06-10 Impact factor: 47.728
Authors: Christian Vollmer; Demie Kepaptsoglou; Jan Leitner; Henner Busemann; Nicole H Spring; Quentin M Ramasse; Peter Hoppe; Larry R Nittler Journal: Proc Natl Acad Sci U S A Date: 2014-10-06 Impact factor: 11.205
Authors: Christine Floss; Frank J Stadermann; John Bradley; Zu Rong Dai; Sasa Bajt; Giles Graham Journal: Science Date: 2004-02-27 Impact factor: 47.728
Authors: Christian Vollmer; Jan Leitner; Demie Kepaptsoglou; Quentin M Ramasse; Ashley J King; Paul F Schofield; Addi Bischoff; Tohru Araki; Peter Hoppe Journal: Sci Rep Date: 2020-11-20 Impact factor: 4.379