Eocene dykes extending over 50 km along the southern margin of the Ladakh batholith (NW India) fall into two main groups showing different orientations, as well as different isotope and trace element geochemistry. Both dyke families formed in the same tectonic setting over a time span of approximately 4 Ma. However, each family is far from monolithic, and therefore we tested several statistical approaches to identify geochemical subgroups from rare earth element (REE) data and relate them to magmatogenetic processes. Hierarchical clustering and multidimensional scaling calculate similarities/dissimilarities among individuals of a population. Both statistical tools, when applied to the Ladakh dykes, reflect the east–west dichotomy. However, detailed quantification of the resulting grouping varies according to input data. Normalization to chon-drites yields slightly different groupings from unnormalized concentration data. Population internal REE normalization provides the most accurate grouping, as revealed by the fact that multiple samples from the same dyke are assigned the closest relatedness. Independently from normalization, east–west dichotomy is mirrored by marked differences in the degree of crustal assimilation and magma evolution, pointing to kilometre-scale geological heterogeneity. Finally, dykes intruding the Ladakh batholith 150 km SE of the present samples are geochemically similar, but cluster as a distinct group.
Heri, A., Bahl, J., Villa, I. (2019). Geochemical discrimination and petrogenetic affinities of dykes intruding the Ladakh batholith, NW India. In R. Sharma, I.M. Villa, S. Kumar (a cura di), Crustal Architecture and Evolution of the Himalaya-Karakoram-Tibet Orogen (pp. 231-250). London : Geological Society of London [10.1144/SP481-2017-150].
Geochemical discrimination and petrogenetic affinities of dykes intruding the Ladakh batholith, NW India
Villa IMUltimo
2019
Abstract
Eocene dykes extending over 50 km along the southern margin of the Ladakh batholith (NW India) fall into two main groups showing different orientations, as well as different isotope and trace element geochemistry. Both dyke families formed in the same tectonic setting over a time span of approximately 4 Ma. However, each family is far from monolithic, and therefore we tested several statistical approaches to identify geochemical subgroups from rare earth element (REE) data and relate them to magmatogenetic processes. Hierarchical clustering and multidimensional scaling calculate similarities/dissimilarities among individuals of a population. Both statistical tools, when applied to the Ladakh dykes, reflect the east–west dichotomy. However, detailed quantification of the resulting grouping varies according to input data. Normalization to chon-drites yields slightly different groupings from unnormalized concentration data. Population internal REE normalization provides the most accurate grouping, as revealed by the fact that multiple samples from the same dyke are assigned the closest relatedness. Independently from normalization, east–west dichotomy is mirrored by marked differences in the degree of crustal assimilation and magma evolution, pointing to kilometre-scale geological heterogeneity. Finally, dykes intruding the Ladakh batholith 150 km SE of the present samples are geochemically similar, but cluster as a distinct group.File | Dimensione | Formato | |
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