Petrology
zahra badrzadeh
Abstract
Abstract The studied Chaltian granitoid is located in the endpoint of the southern Sanandaj–Sirjan Zone. This pluton has Low-Al trondhjemitic composition with tholeiitic to transitional nature. The intrusion has been intruded in the early Mesozoic volcanic and sedimentary rocks. According to U-Pb ...
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Abstract The studied Chaltian granitoid is located in the endpoint of the southern Sanandaj–Sirjan Zone. This pluton has Low-Al trondhjemitic composition with tholeiitic to transitional nature. The intrusion has been intruded in the early Mesozoic volcanic and sedimentary rocks. According to U-Pb SHRIMP age dating of zircon grains, this pluton was intruded at the 187.5 ±3.2Ma ago. Studied pluton has low Al2O3, Sr/Y, (La/Yb)N ratio and less fractionated REE pattern. In the primitive mantle normalized spider diagrams, studied samples show enrichment of LIL elements such as K, Rb, Ba and Th relative to HFS elements and has negative anomaly in Ta, Nb and Ti elements, which are considered characteristic of magmas generated in subduction related settings. In terms of their origin, based on geological and geochemical characteristics, trondhjemitic melt has been generated by low pressure dehydration melting of amphibolitic source in an continental extensional tectonic setting related to subduction environment.
A. N. Fazlnia
Abstract
A barrovian-type metamorphism occurred in the mafic rocks from the Qori complex (South Sanandaj - Sirjan zone), because of a regional arc-related metamorphism with a peak metamorphic condition of 700 °C and 8.5 kbar at 147 million years ago. As a result of the process, the rocks changed to migmatite. ...
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A barrovian-type metamorphism occurred in the mafic rocks from the Qori complex (South Sanandaj - Sirjan zone), because of a regional arc-related metamorphism with a peak metamorphic condition of 700 °C and 8.5 kbar at 147 million years ago. As a result of the process, the rocks changed to migmatite. Trondhjemitic granitoids were formed as the dike form because parts of the melts can be extracted from the migmatites. Decreasing and increasing trace and rare earth elements in the amphibolites and trondhjemites were resulted of stability or instability in the metamorphic minerals during peak of the metamorphism, which caused migmatization and also formation of trondhjemite. Based on the partition coefficients of elements in different minerals, light rare earth elements (LREE) were mostly controlled by hornblende and garnet and apatite (but not a lot) during the partial melting of the amphibolites. Related to the LREE, heavy rare earth elements (HREE) and Y were controlled by apatite and garnet. Elements with high field strength (HFS), such as Zr, Nb, Ta and Th were controlled and distributed by hornblende and ilmenite. Large ionic lithophile elements (LILE) such as Sr, Ba and Rb showed that plagioclase and biotite were main minerals to control and distribute the elements. The evidence suggests that the Qori trondhjemitic granitoids are similar to the Al-poor trondhjemites, which are the result of partial melting of the garnet-hornblende from the amphibolitic protolith in presence of calcic plagioclase as stable phase.