The Winchcombe meteorite – a regolith breccia from a rubble-pile CM chondrite asteroid
2022
Suttle, Martin D | Daly, Luke | Jones, Rhian H | Jenkins, Laura | Van Ginneken, Matthias | Mitchell, Jennifer T | Bridges, John C | Hicks, Leon J | Johnson, Diane | Rollinson, Gavyn | Taylor, Rich | Genge, Matthew J | Schroeder, Christian | Bonsall, Emily | Trimby, Patrick | The Open University | University of Glasgow | University of Manchester | University of Glasgow | University of Kent | University of Plymouth | University of Leicester | University of Leicester | Cranfield University | University of Exeter | Carl Zeiss Microscopy | Imperial College London | Biological and Environmental Sciences | Biological and Environmental Sciences | Oxford Nanopore Technologies | 0000-0002-7935-6039
The Winchcombe meteorite is a CM chondrite breccia composed of eight distinct lithological units plus a cataclastic matrix. The degree of aqueous alteration varies between intensely altered CM2.0 and moderately altered CM2.6. Although no lithology dominates, three heavily altered rock types (CM2.1-2.3) represent >70 area%. Tochilinite-cronstedtite intergrowths (TCIs) are common in several lithologies. Their compositions can vary significantly, even within a single lithology, which can prevent a clear assessment of alteration extent if only TCI composition is considered. We suggest this is due to early alteration under localised geochemical microenvironments creating a diversity of compositions and because later reprocessing was incomplete, leaving a record of the parent body’s fluid history. In Winchcombe fragments of primary accretionary rock are held within a cataclastic matrix (~15 area%). This material is impact-derived fallback debris. Its grain size and texture suggest that the disruption of the original parent asteroid responded by intergranular fracture at grain sizes <100 µm, while larger phases, such as whole chondrules, splintered apart. Re-accretion formed a poorly lithified body. During atmospheric entry, the Winchcombe meteoroid broke apart with new fractures preferentially cutting through the weaker cataclastic matrix and separating the breccia into its component clasts. The strength of the cataclastic matrix imparts a control on the survival of CM chondrite meteoroids. Winchcombe’s unweathered state and diversity of lithologies makes it an ideal sample for exploring the geological history of the CM chondrite group.
Show more [+] Less [-]Additional authors: H. Mansour, S. Piazolo, T. Salge, R. Heard, R. Findlay, A. J. King, H. C. Bates, M. R. Lee, N. R. Stephen, F. M. Willcocks, R. C. Greenwood, I. A. Franchi, S. S. Russell, C. S. Harrison, P. F. Schofield, N. V. Almeida, C. Floyd, P.-E. Martin, K. H. Joy, P. J. Wozniakiewicz, D. Hallatt, M. J. Burchell, L. S. Alesbrook, V. Spathis, L. T. Cornwell, A. Dignam
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