Abundance, Major Element Composition and Size of Components and Matrix in CV, CO and Acfer 094 Chondrites

The relative abundances and chemical compositions of the macroscopic components or "inclusions" (chondrules and refractory inclusions) and fine-grained mineral matrix in chondritic meteorites provide constraints on astrophysical theories of inclusion formation and chondrite accretion. We present new techniques for analysis of low count per pixel Si, Mg, Ca, Al, Ti and Fe x-ray intensity maps of rock sections, and apply them to large areas of CO and CV chondrites, and the ungrouped Acfer 094 chondrite. For many thousands of manually segmented and type-identified inclusions, we are able to assess, pixel-by-pixel, the major element content of each inclusion. We quantify the total fraction of those elements accounted for by various types of inclusion and matrix. Among CO chondrites, both matrix and inclusion Mg to Si ratios approach the solar (and bulk CO) ratio with increasing petrologic grade, but Si remains enriched in inclusions relative to matrix. The oxidized CV chondrites with higher matrix-inclusion ratios exhibit more severe aqueous alteration (oxidation), and their excess matrix accounts for their higher porosity relative to reduced CV chondrites. Porosity could accommodate an original ice component of matrix as the direct cause of local alteration of oxidized CV chondrites. We confirm that major element abundances among inclusions differ greatly, across a wide range of CO and CV chondrites. These abundances in all cases add up to near-chondritic (solar) bulk abundance ratios in these chondrites, despite wide variations in matrix-inclusion ratios and inclusion sizes: chondrite components are complementary. This "complementarity" provides a robust meteoritic constraint for astrophysical disk models

Online Materials for Populations of Calcium-and Aluminum Inclusions and Rare Earth Elements in Ornans-group Carbonaceous Chondrites as Associated with the PhD Dissertation of Ellen J. Crapster-Pregont (Constraining the Chemical Environment and Processes in the Protoplanetary Disk: Perspective from Populations of Calcium-and Aluminum-rich Inclusions in Ornans-group and Metal-rich Chondrules in Renazzo-group Carbonaceous Chondrites)

All of the files herein are supporting data and information from the dissertation completed by Ellen Crapster-Pregont as part of the requirement for a PhD in geochemistry from Columbia University. This dissertation research was advised by Dr. Denton Ebel and the defense committee consisted of Drs. Terry Plank, Dave Walker, Jon Friedrich, and Ben Bostick. The accompanying files are associated with the portion of the dissertation that addresses refractory inclusions and rare Earth elements in various components in Ornans-group carbonaceous chondrites (chapters 1 through 3 and appendices A through D in the dissertation). The following files represent digital copies of the data used to create the plots, figures, tables, and interpretations found within the dissertation. Data range from electron probe microanalyzer element x-ray intensity maps to LA-ICP-MS concentrations to modal phase maps. Detailed descriptions of the contents of each file can be found in “file_descriptions”. See 'show full item record' for the citation and DOI of a full copy of this dissertation

Constraining the Chemical Environment and Processes in the Protoplanetary Disk: Perspective from Populations of Calcium- and Aluminum-rich Inclusions in Ornans-group and Metal-rich Chondrules in Renazzo-group Carbonaceous Chondrites

Carbonaceous chondrites have an approximately solar bulk composition, with some exceptions (e.g. H), and exhibit a range of parent body alteration. Investigations of both pristine and altered chondrites yield valuable insight into the processes and conditions of the early Solar System prior to and resulting in the planets we observe today. Such insight and the dynamic models developed by astrophysicists are constrained by chemical, mineralogical, and textural characteristics of chondrite components (chondrules, refractory inclusions, metal, and matrix). This dissertation uses a variety of chondritic components to address the following: 1) what do correlations within a population of refractory inclusions reveal about early Solar System conditions; 2) what is the distribution of trace elements among chondrite components and how does this affect component formation from precursor aggregation to chondrite accretion; and 3) can metal associated with chondrules further our understanding of chondrule formation and/or deformation? The first two objectives were investigated using suite of carbonaceous Ornans-group (CO) chondrites of varying petrologic grades (Colony CO3.0, Kainsaz CO3.2, Felix CO3.3, Moss CO3.6, and Isna CO3.8). These chondrites were analyzed using several analytical techniques including: electron microprobe element mapping, a modal phase analysis algorithm, and laser ablation inductively coupled plasma mass spectrometry. Within the comprehensive dataset of refractory inclusion characteristics (area, major mineralogy, bulk major chemistry, texture, and rare Earth element (REE) patterns and abundances) there is an overwhelming lack of correlations implying that thermal processing prior to accretion was stochastic and that sorting was minimal. Only two CO chondrites were analyzed for REE abundances (Colony and Moss). While refractory inclusions exhibit the greatest enrichments in REE relative to CI, after modal recombination chondrule glass contributes most significantly to the bulk REE budget in both chondrites. The bulk mean REE patterns for both Colony and Moss are flat and approximately CI in abundance while the mean REE patterns for components are nearly flat with relative enrichments (~10x CI for both chondrule glass and refractory inclusions) or depletions (chondrule olivine) relative to CI. Lack of correlations between REE and other characteristics, nearly flat REE patterns and nearly equivalent enrichment factors relative to CI across chondrite groups, including the CO chondrites analyzed here, implies that REE were equilibrated in precursor material prior to chondrite component formation. We propose a scenario for the equilibration of REE with vapor-solid or solid-solid reactions with subsequent accretion of chondrite components. Metal-rich chondrules in Acfer 139, a carbonaceous Renazzo-group (CR) chondrite were used to address the final objective. Chemical information was obtained using electron microprobe quantitative analysis and element mapping, electron backscatter diffraction was used to analyze the crystal structure of the metal nodules, and computed tomography provided insight into the 3D relationships of the metal. Eight chondrules with abundant metal nodules, both as rims and within the chondrule interior, were analyzed in detail. Chondrule A is of particular interest as it contains three concentric metal layers. A majority of the metal nodules fall on the calculated condensation trajectory of Co/Ni in a vapor of solar composition with the interior metal nodules containing higher Ni wt% and Co wt% than the rim nodules. Twinning is evident in many of the metal nodules and could indicate a ubiquitous parent body deformation process. Chemical inhomogeneity of Ni only occurs within the metal nodules of chondrule A and implies these metal nodules were reheated to high temperatures. The combination of chemical inhomogeneity, multiple sets of twins, and other evidence of strain imply that the formation of these chondrules was not straightforward and involved multiple iterations of heating, and potentially addition of material. A plausible model of chondrule formation in the early Solar System must be able to account for this more complicated thermal and alteration history and produce the chemical and textural variety of chondrules present in the region of chondrite accretion