Journal
PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA
Volume 118, Issue 13, Pages -Publisher
NATL ACAD SCIENCES
DOI: 10.1073/pnas.2026779118
Keywords
iron meteorites; carbon; sulfur; planetary accretion; planetesimals
Categories
Funding
- Integrated NSF Support Promoting Interdisciplinary Research and Education Program [AST1344133]
- National Aeronautics and Space Administration [80NSSC19K0959, XRP NNX16AB48G, XRP 80NSSC20K0259]
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During the formation of terrestrial planets, volatile loss can occur through various processes such as nebular processing, planetesimal differentiation, and planetary accretion. Iron meteorites are studied as a record of volatile loss during planetesimal processing, revealing that significant open-system silicate melting and volatile loss are crucial in shaping the volatile inventory of terrestrial planets. The composition of parent body cores, characterized by different C/S ratios, suggests that processes affecting composite silicate/iron planetesimals play a key role in shaping volatile compositions.
During the formation of terrestrial planets, volatile loss may occur through nebular processing, planetesimal differentiation, and planetary accretion. We investigate iron meteorites as an archive of volatile loss during planetesimal processing. The carbon contents of the parent bodies of magmatic iron meteorites are reconstructed by thermodynamic modeling. Calculated solid/molten alloy partitioning of C increases greatly with liquid S concentration, and inferred parent body C concentrations range from 0.0004 to 0.11 wt%. Parent bodies fall into two compositional clusters characterized by cores with medium and low C/S. Both of these require significant planetesimal degassing, as metamorphic devolatilization on chondrite-like precursors is insufficient to account for their C depletions. Planetesimal core formation models, ranging from closedsystem extraction to degassing of a wholly molten body, show that significant open-system silicate melting and volatile loss are required to match medium and low C/S parent body core compositions. Greater depletion in C relative to S is the hallmark of silicate degassing, indicating that parent body core compositions record processes that affect composite silicate/iron planetesimals. Degassing of bare cores stripped of their silicate mantles would deplete S with negligible C loss and could not account for inferred parent body core compositions. Devolatilization during small-body differentiation is thus a key process in shaping the volatile inventory of terrestrial planets derived from planetesimals and planetary embryos.
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