Impact shock origin of diamonds in ureilite meteorites

Fabrizio Nestola; Cyrena A. Goodrich; Marta Morana; Anna Barbaro; Ryan S. Jakubek; Oliver Christ; Frank E. Brenker; M. Chiara Domeneghetti; M. Chiara Dalconi; Matteo Alvaro; Anna M. Fioretti; Konstantin D. Litasov; Marc D. Fries; Matteo Leoni; Nicola P. M. Casati; Peter Jenniskens; Muawia H. Shaddad

doi:10.1073/pnas.1919067117

Edited by Mark Thiemens, University of California San Diego, La Jolla, CA, and approved August 12, 2020 (received for review October 31, 2019)

Significance

The origin of diamonds in ureilites is still a debated issue among the scientific community, with significant implications for the sizes of early Solar System bodies. We investigated three diamond-bearing ureilites by a multimethodological approach using scanning electron microscopy, micro X-ray diffraction, transmission electron microscopy, and micro-Raman spectroscopy, with the aim of determining the origin of the diamonds. Our results show that formation of both microdiamonds and nanodiamonds in ureilites can be explained by impact shock events on a small planetesimal and does not require long growth times at high static pressures within a Mercury- or Mars-sized body.

Abstract

The origin of diamonds in ureilite meteorites is a timely topic in planetary geology as recent studies have proposed their formation at static pressures >20 GPa in a large planetary body, like diamonds formed deep within Earth’s mantle. We investigated fragments of three diamond-bearing ureilites (two from the Almahata Sitta polymict ureilite and one from the NWA 7983 main group ureilite). In NWA 7983 we found an intimate association of large monocrystalline diamonds (up to at least 100 µm), nanodiamonds, nanographite, and nanometric grains of metallic iron, cohenite, troilite, and likely schreibersite. The diamonds show a striking texture pseudomorphing inferred original graphite laths. The silicates in NWA 7983 record a high degree of shock metamorphism. The coexistence of large monocrystalline diamonds and nanodiamonds in a highly shocked ureilite can be explained by catalyzed transformation from graphite during an impact shock event characterized by peak pressures possibly as low as 15 GPa for relatively long duration (on the order of 4 to 5 s). The formation of “large” (as opposed to nano) diamond crystals could have been enhanced by the catalytic effect of metallic Fe-Ni-C liquid coexisting with graphite during this shock event. We found no evidence that formation of micrometer(s)-sized diamonds or associated Fe-S-P phases in ureilites require high static pressures and long growth times, which makes it unlikely that any of the diamonds in ureilites formed in bodies as large as Mars or Mercury.

Footnotes

↵¹To whom correspondence may be addressed. Email: fabrizio.nestola{at}unipd.it or goodrich{at}lpi.usra.edu.

Author contributions: F.N. and C.A.G. designed research; F.N., C.A.G., M.M., A.B., O.C., F.E.B., A.M.F., and N.P.M.C. performed research; R.S.J., F.E.B., and M.D.F. contributed new reagents/analytic tools; F.N., C.A.G., M.M., A.B., O.C., M.C. Domeneghetti, M.C. Dalconi, M.A., A.M.F., M.L., and N.P.M.C. analyzed data; and F.N., C.A.G., M.M., A.B., R.S.J., O.C., F.E.B., M.C. Domeneghetti, M.C. Dalconi, M.A., A.M.F., K.D.L., M.D.F., M.L., N.P.M.C., P.J., and M.H.S. wrote the paper.
The authors declare no competing interest.
This article is a PNAS Direct Submission.
This article contains supporting information online at https://www.pnas.org/lookup/suppl/doi:10.1073/pnas.1919067117/-/DCSupplemental.

Data Availability.

All study data are included in the paper, SI Appendix, and Datasets S1–S3. The three diffractograms for AhS 209b, AhS 72, and NWA 7983 Diamond 2 are available in a .txt format (intensity vs. 2θ angle) and can be visualized using any graphical software (Datasets S1–S3).

This open access article is distributed under Creative Commons Attribution-NonCommercial-NoDerivatives License 4.0 (CC BY-NC-ND).

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