An appraisal of geochemical signatures of komatiites from the greenstone belts of <scp>Dharwar Craton, India</scp>: Implications for temporal transition and <scp>Archean</scp> upper mantle hydration

Ganguly, Sohini; Santosh, M.; Manikyamba, C.

doi:10.1002/gj.3532

Cited by 7 publications

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“…The origin and evolution of Archean granite‐greenstone belts are subjects of immense interest in understanding the mantle processes, crustal growth, and tectonic evolution of the early Earth. Particularly, the volcanic supracrustals of greenstone belts represent magmatic episodes associated with Precambrian terrane accretion, continental lithosphere evolution and crustal growth through subduction–accretion processes, plume–arc cohabitation, plume–craton interactions, and arc–continent collisions (Barnes & Van Kranendonk, 2014; Dostal & Mueller, 2013; Ganguly, Santosh, & Manikyamba, 2019; Ganguly & Yang, 2018; Ghose & Saha, 2018; Manikyamba et al, 2017; Manikyamba & Kerrich, 2012; Ray et al, 2013; Smithies, Champion, Van Kranendonk, Howard, & Hickman, 2005). Mafic magmatism associated with Precambrian Large Igneous Provinces (LIPs; Mc Call, 2003; Rey, Philippot, & Thebaud, 2003; Sylvester, Campbell, & Bowyer, 1997) as exemplified in Black Range Dyke Swarms in Pilbara Craton, Australia (Heaman, 2008; Wingate, 1999), Mackenzie LIP in northwest Canada (Heaman & LeCheminant, 1993; LeCheminant & Heaman, 1989), Garder Province of southern Greenland (Upton, Emeleus, Heaman, Goodenough, & Finch, 2003) and Dalarna complex in central Scandinavia (Soderlund, Elmings, Ernst, & Schissel, 2006; Suominen, 1991), and numerous Phanerozoic equivalents (Coffin & Eldholm, 1994; Heaman, 2008) are characterized by voluminous magmatic pulses in short durations and giant dyke swarms that served as transport systems for mantle‐derived magmas.…”

Section: Introductionmentioning

confidence: 99%

Mafic volcanic rocks of western Iron Ore Group, Singhbhum Craton, eastern India: Geochemical evidence for ocean–continent convergence

et al. 2020

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Precambrian mafic magmatism is an important global episode which played a significant role in the crustal evolution. In India, Singhbhum Craton being the oldest craton, witnessed significant occurrences of Precambrian geological activity, marked by several episodes of volcanism, plutonism, sedimentation spanning from Palaeoarchean to Mesoproterozoic age. Here we present petrological and geochemical characteristics of Precambrian mafic volcanic rocks (occurring in western Iron Ore Group (IOG), Singhbhum Craton, eastern India) to evaluate their petrogenetic aspects, tectonic setting, and magma generation. The mafic volcanic rocks are porphyritic in nature with the phenocrysts of plagioclase and groundmass composed of clinopyroxene, plagioclase, ilmenite, and volcanic glass. These rocks are mostly tholeiitic, sometimes with a transitional behaviour towards calc‐alkaline nature and display basalt‐basaltic andesite affinity. These mafic volcanic rocks also preserve geochemical signatures (high Nb/U, Nb/La, [Nb/Th]pm ratios) in support of Nb‐enriched basalts and are classified as Nb‐enriched basalts (NEB; Nb > 7 ppm) and high‐Nb basalts (HNB; Nb > 20 ppm) on the basis of Nb concentrations and mantle normalized Nb/La ratios (>0.5). The NEBs and HNBs are marked by lesser magnitude of negative Nb anomalies with high (Nb/Th)pm, (Nb/La)pm, and Nb/U ratios as compared to normal arc basalts. Several major element oxides, trace elements, and selected element ratios (like SiO2, CaO/Al2O3, Y, V/Cr, Zr/Nb, and ∑REE) show systematic variations with MgO which suggests role of magmatic fractionation. Chondrite‐normalized REE patterns for NEB and HNB rocks exhibit uniform LREE enrichment with distinct Eu negative anomalies while primitive mantle‐normalized incompatible trace element patterns reflect enrichment in LILE and LREE with prominent Nb‐Ta anomalies. Different HFSE ratios corroborate a subduction related setting for magma generation formed by ∼10%–20% melting in the domain of garnet lherzolite. Relative enrichment of LILE and LREE with depleted HFSE characteristics attest a garnet‐bearing mantle source and melt extraction with garnet in the residue. Geochemical signatures suggest that the genesis of NEB and HNB is attributable to slab‐melting and wedge hybridization processes during matured stages of subduction. Selected incompatible trace element ratios for the studied mafic volcanic rocks invoke an enriched (EM1‐EM2 type) mantle source and unequivocally suggest effects of continental crustal assimilation of the parent magma. Liquid immiscibility has played an important role as a differentiation mechanism leading to presence of high and low FeO types. The IOG mafic volcanic rocks preserve distinct geochemical signatures of matured stage of subduction, slab melting, crustal contamination and magma generation at an Archean ocean–continent convergent margin setting.

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Section: Introductionmentioning

confidence: 99%

Mafic volcanic rocks of western Iron Ore Group, Singhbhum Craton, eastern India: Geochemical evidence for ocean–continent convergence

et al. 2020

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“…These studies reflect on the role of plate tectonics during the Paleo-Mesoarchean time frame. Ganguly et al (2019) evaluated the geochemical signatures of komatiites from Mesoarchean Sargur Group and Neoarchean Dharwar Supergroup greenstone belts of Dharwar Craton, corroborated possible proponents for Archean upper mantle hydration and suggested a gradual temporal transition of mantle characteristics during Meso-Neoarchean times. Recently, Pahari et al (2019) have reported U-Pb zircon age and detailed geochemistry of the island arc basalts and Nb-enriched basalts from the Kudremukh greenstone belt of western Dharwar Craton which were erupted at 2498+43 Ma and these are geochemically similar with the Phanerozoic counterparts.…”

Section: Greenstone Belts: Volcano-sedimentary Sequencesmentioning

confidence: 64%

Annals of Precambrian Lithospheric Evolution and Metallogeny in the Dharwar Craton, India: Recent Paradigms and Perspectives

Manikyamba¹,

Ganguly²

2020

PINSA

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This article brings out a comprehensive overview of the scientific studies that have been executed in different parts of Dharwar Craton during last four years 2016-2020. Recent trends of research and scientific perspectives have emphasized on integrated approaches involving a wide spectrum of geochemical, isotopic and geochronological proxies to address fundamental questions in the Dharwar Craton on Precambrian evolution of the earth, episodes and mechanisms of crust generation and the mantle dynamics. The excellent preservation of Precambrian lithologies including basement gneisses, volcano-sedimentary sequences of greenstone belts, granitoid plutons, ultramafic-mafic complexes, ultrapotassic magmatism and dyke swarms in the Dharwar Craton have provided an opportunity for understanding the geodynamic transitions in the secular evolution of the Earth. A four year status report including the principal lithological associations of Dharwar Craton have been described in this communication detailing the scientific investigations and their implications are brought out under various sections. The salient aspects of the scientific contributions on granite-greenstone terranes of Dharwar Craton emphasising on geochronology, geochemistry, biogeochemical processes, geodynamics and mineralization.

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“…The basal terrestrial deposits also provide insights on the Palaeoarchaean fluvial systems. Ganguly, Santosh , and Manikyamba (—this issue) present an overview of the geochemical features of the Sargur Group and Dharwar Supergroup greenstone belts of the Dharwar Craton in southern India. The Mesoarchean–Neoarchean komatiites in Dharwar provide evidence for heterogeneous, hydrated Archean upper mantle trapped by ascending mantle plumes.…”

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Evolution of the Indian subcontinent: Introduction

et al. 2019

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An appraisal of geochemical signatures of komatiites from the greenstone belts of Dharwar Craton, India: Implications for temporal transition and Archean upper mantle hydration

Cited by 7 publications

References 149 publications

Mafic volcanic rocks of western Iron Ore Group, Singhbhum Craton, eastern India: Geochemical evidence for ocean–continent convergence

Mafic volcanic rocks of western Iron Ore Group, Singhbhum Craton, eastern India: Geochemical evidence for ocean–continent convergence

Annals of Precambrian Lithospheric Evolution and Metallogeny in the Dharwar Craton, India: Recent Paradigms and Perspectives

Evolution of the Indian subcontinent: Introduction

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