Potential of VIS-IR imaging spectroscopy and SEM-EDS and EMPA to map the mineralogical composition of NWA 7317 (CR6)

Asteroid compositional analysis relies on comparing reflectance spectra with laboratory data from well-characterized meteorites. To advance this comparison, we performed a comprehensive laboratory analysis on a slab of the Northwest Africa (NWA) 7317-CR6 carbonaceous chondrite. We employed high-resolution Visible-Infrared (VIS-IR) imaging spectroscopy (0.4-5.1 mu m) using the SPIM hyperspectral facility, integrated with high-spatial-resolution elemental mapping via SEM-EDS and EMPA-WDS. This multi-technique approach enabled the retrieval of surface composition at high spectral and spatial resolutions. Our results, supported by ICA/PCA and K-means classification methodologies, highlight the challenges of integrating VIS-IR spectroscopy and SEM/EMPA at the micrometer scale. While both techniques consistently infer an overall poikiloblastic/metamorphic texture dominated by an olivine and pyroxene-rich matrix, their combined use requires a critical approach for robust analysis. The absence of the 3 mu m absorption band indicates high temperatures during thermal metamorphism on the NWA 7317 parent body. Although FeNi metallic alloys and Fe-sulfide inclusions contribute to the VIS-IR spectroscopic signal, they are not clearly distinguishable from each other. Furthermore, minor phases like plagioclase and chromite de