Pecora Escarpment 91002: A member of the new Rumuruti (R) chondrite group

Abstract— Pecora Escarpment (PCA)91002 is a light/dark‐structured chondrite breccia related to Carlisle Lakes and Rumuruti; the meteorite contains ∼10–20 vol% equilibrated (type −5 and −6) clasts within a clastic groundmass, much of which was metamorphosed to type‐3.8 levels. The olivine compositional distribution forms a tight cluster that peaks at Fa 38–40 ; by contrast, low‐Ca pyroxene compositions are highly variable. Opaque phases identified in PCA91002 and its paired specimen, PCA91241, include pyrrhotite, pentlandite, pyrite, chromite, ilmenite, metallic Cu and magnetite. The majority of the rock is of shock stage S3‐S4; there are numerous sulfide‐rich shock veins and 50‐μm plagioclase melt pockets. Instrumental neutron activation analysis shows that, unlike Carlisle Lakes and ALH85151, PCA91002 exhibits no Ca enrichment or Au depletion; because PCA91002 is relatively unweathered, it seems probable that the Ca and Au fractionations in Carlisle Lakes and ALH85151 were caused by terrestrial alteration. The Rumuruti‐like (formerly Carlisle‐Lakes‐like) chondrites now include eight separate meteorites. Their geochemical and petrographic similarities suggest that they constitute a distinct chondrite group characterized by unfractionated refractory lithophile abundances (0.95 ± 0.05x CI), high bulk Δ 17 O, a low chondrule/groundmass modal abundance ratio, mean chondrule diameters in the 400 ± 100 μm range, abundant NiO‐bearing ferroan olivine, sodic plagioclase, titanian chromite, abundant pyrrhotite and pentlandite and negligible metallic Fe‐Ni. We propose that this group be called R chondrites after Rumuruti, the only fall. The abundant NiO‐bearing ferroan olivine grains, the occurrence of Cu‐bearing sulfide, and the paucity of metallic Fe‐Ni indicate that R chondrites are highly oxidized. It is unlikely that appreciable oxidation took place on the parent body because of the essential lack of plausible oxidizing agents ( e.g ., magnetite or hydrated silicates). Therefore, oxidation of R chondrite material must have occurred in the nebula. A few type‐I porphyritic olivine chondrules containing olivine grains with cores of Fa 3–4 composition occur in PCA91002; these chondrules probably formed initially as metallic‐Fe‐Ni‐bearing objects at high nebular temperatures. As temperatures decreased and more metallic Fe was oxidized, these chondrules accreted small amounts of oxidized material and were remelted. The ferroan compositions of the >5‐μm olivine grains in the R chondrites reflect equilibration with fine‐grained FeO‐rich matrix material during parent body metatnorphism.