Geochemical characteristics of mafic and felsic igneous rocks (1.9–1.75 Ga) in the Lesser Himalaya: Regional variation and its implications for tectonic setting

Major and trace element and Nd–Hf isotopic compositions of Paleoproterozoic meta‐igneous rocks from the lower part of the Lesser Himalayan sequence provide insights into the nature of their source mantle and its tectonic setting. We observed bimodal (basaltic and rhyolitic) magmatic compositions in...

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Bibliographic Details
Published in:The island arc 2020-01, Vol.29 (1), p.n/a
Main Authors: Shinjo, Ryuichi, Amuro, Tomoki, Oura, Kohei, Oshiro, Kazuya, Tahara, Shiro, Sakai, Harutaka
Format: Article
Language:English
Subjects:
Chemical composition
Depletion
Geochemistry
Hf isotope
Hot spots (geology)
Hydrothermal alteration
Igneous rocks
Isotopes
Kuncha Formation
Late Paleoproterozoic
Lava
Lesser Himalaya
Mantle plumes
Naudanda Formation
Nd isotope
Niobium
Passive margins
Plates (tectonics)
Regional variations
Subduction
Subduction (geology)
Supercontinent Columbia
Tantalum
tectonic setting
Tectonics
Trace elements
Volcanic activity
Volcanism
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Summary:Major and trace element and Nd–Hf isotopic compositions of Paleoproterozoic meta‐igneous rocks from the lower part of the Lesser Himalayan sequence provide insights into the nature of their source mantle and its tectonic setting. We observed bimodal (basaltic and rhyolitic) magmatic compositions in these rocks; this type of volcanism generally occurs in areas of extensional tectonics, particularly rifts. Two types of mafic rocks are identified: within‐plate type (subduction‐unrelated, enriched mantle derived) rocks and Nb–Ta‐depleted, continental arc‐like rocks. Within‐plate type mafic rocks are dominant in the eastern Nepal, though similar rocks are also found in western Nepal. Although models for the tectonic setting of these igneous rocks remain controversial (e.g. passive margin, continental arc, continental rift with possible hotspot), our new geochemical data support the rift model associated with mantle plume activity, which evolved to a passive margin. The Nb–Ta‐depleted, arc‐like rocks have lower εNd (t) (−1.7 to 1.7) and εHf (t) (0.9–4.4) than within‐plate type rocks; we consider that these rocks are formed from the interaction of mantle‐derived magmas with crustal components. All felsic rocks have similar or slightly lower εNd (t) (−5.2 to −0.1) and εHf (t) (−6.5 to 2.7) values relative to arc‐like mafic rocks, suggesting relatively limited crustal interaction. They may be derived from juvenile crust of underplated mafic magmas. Most of the felsic rocks have remarkably low Nb/Ta ratios (
ISSN:1038-4871
1440-1738
DOI:10.1111/iar.12369