Evolution of a Mesoarchean suprasubduction zone mantle wedge in the Dharwar Craton, southern India: Evidence from petrology, geochemistry, zircon U–Pb geochronology, and Lu–Hf isotopes

Han, Yue-Sheng; Santosh, M.; Ganguly, Sohini; Li, Shanshan

doi:10.1002/gj.3440

Cited by 12 publications

(5 citation statements)

References 76 publications

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“…Based on the geochemical and isotopic data, Santosh and Li (2018) suggested that extensive arc magmatism of similar age evidenced from the adjacent greenstone belts which mark the trace of ocean closure and correspond to multiple converge of microblocks at the end of Archean which are responsible for building the cratonic mosaic of the Dharwar. Based on the mineral chemistry, zircon U-Pb geochronology, rare earth element (REE), Lu-Hf isotopes, and whole rock geochemistry, Han et al (2019) investigated a suite of serpentinized dunite, dunite, pyroxenite, and clinopyroxenite from an ultramafic complex situated along the collisional suture between the western Dharwar Craton (WDC) and the Central Dharwar Craton (CDC). Zircon U-Pb age range from 2.9-2.6 Ga with an early Paleoproterozoic (ca.…”

Section: Greenstone Belts: Volcano-sedimentary Sequencesmentioning

confidence: 99%

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

Manikyamba¹,

Ganguly²

2020

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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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Section: Greenstone Belts: Volcano-sedimentary Sequencesmentioning

confidence: 99%

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

Manikyamba¹,

Ganguly²

2020

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“…The Chitradurga greenstone belt and associated shear zone marks the boundary between the WDC and the CDC and the Kolar–Kadiri greenstone belt divides the eastern edge of the CDC from the EDC. The 500‐km‐long north–south‐trending Closepet granite batholith is located within the CDC at the eastern margin of the Chitradurga greenstone belt (Chadwick et al, ; Chardon et al, , ; Han, Santosh, Ganguly, & Li, ; Jayananda, Peucat, et al, ; Jayananda, Tsutsumi, et al, ; Li et al, ). This batholith was formed by intrusion and crystallization of mantle‐derived mafic magma into pre‐existing TTG gneiss at 2.56–2.51 Ga causing fluid release and crustal anatexis (Moyen et al, ).…”

Section: Regional Geologymentioning

confidence: 99%

“…The contact between WDC and EDC is not sharp and a transition zone extending from Closepet granite to Chitradurga shear zone corresponds to the boundary between these two sectors of Dharwar Craton which has been demarcated as the Central Dharwar Province (CDP) or Central Dharwar Craton (CDC) based on magmatic and metamorphic age data Peucat et al, 2013). Based on U-Pb zircon ages and Nd isotope data, Peucat et al (2013) divided the Dharwar Craton into western (Chadwick et al, 2000;Chardon et al, 2008Chardon et al, , 2011Han, Santosh, Ganguly, & Li, 2019;Jayananda, Peucat, et al, 2013;Jayananda, Tsutsumi, et al, 2013;Li et al, 2018). This batholith was formed by intrusion and crystallization of mantle-derived mafic magma into pre-existing TTG gneiss at 2.56-2.51 Ga causing fluid release and crustal anatexis (Moyen et al, 2001).…”

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confidence: 99%

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

2019

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Archean ultramafic–mafic magmatism associated with dynamic mantle melting processes represents an integral part of crustal evolution and continental growth. Archean mantle plumes and their high temperature derivatives in komatiitic magmas provide a cornerstone in understanding the thermal and chemical evolution of the early Earth and its mantle. In this study, we evaluate the geochemical characteristics of the temporally distinct Sargur Group and Dharwar Supergroup greenstone belts of Dharwar Craton in southern India. The komatiites associated with these greenstone belts are characterized by Al‐depleted and Al‐undepleted compositions. Their MgO, Ni, Co, and Cr concentrations reflect primitive, undifferentiated nature of precursor melts, whereas the HFSE and REE chemistry corroborates high‐degree (30–50%) partial melting of mantle with prominent role of majorite garnet and perovskite in the generation of komatiitic melts. The Al‐depleted komatiites were formed at a greater depth (~13 GPa) by equilibrium melting leaving a garnet‐bearing residue. The resultant komatiitic melt retained buoyancy under extreme pressure and high temperature conditions, segregated and accumulated in the ambient peridotite mantle source and subsequently escaped with progressive decrease in pressure in the ascending plume. The Al‐undepleted and relatively rare Al‐enriched komatiites were derived by fractional melting at intermediate to shallow depths after the discharge of a large proportion of melt ensued by the collapse and entrance of residual garnet into the melt phase. The Mesoarchean–Neoarchean Dharwar komatiites provide evidence for heterogeneous, hydrated Archean upper mantle trapped by ascending mantle plumes. The non‐plume, arc‐related signatures invoke contributions from (a) sub‐cratonic lithospheric mantle roots influenced by ancient subduction events and (b) hydrated Archean upper mantle. The Sargur Group and Dharwar Supergroup komatiites record a distinct temporal transition and geochemical heterogeneity in the Archean mantle beneath the Dharwar Craton and can be attributed to Archean upper mantle hydration by flat slab subduction of >3.3 Ga oceanic crust at shallow level with vestiges of primordial oceanic crust forming deep cratonic mantle roots beneath the Dharwar Craton. The temporal transition towards mantle hydration beneath Dharwar Craton during the Mesoarchean can be correlated with the onset of subduction‐driven plate tectonics and ocean–crust–mantle interactions.

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“…Other than those, the oldest Mesoarchaean-Palaeoproterozoic (c. 3000-2450 Ma) granulite-facies rocks in India are also reported from the Coorg block (Santosh et al 2015;Amaldev et al 2016), Karimnagar Granulite Belt (Santosh et al 2004;Prakash et al 2017) and the southern end of the Dharwar craton (Northern Granulite Terrane or Salem Block) that continues up to the Palghat-Cauvery Shear System (PCSS) within the Southern Granulite Terrane (SGT) (e.g. Rao et al 1996;Bhaskar Rao et al 2003;Braun & Kriegsman, 2003;Ghosh et al 2004;Clark et al 2009;Anderson et al 2012;Peucat et al 2013;Ram Mohan et al 2013;Santosh et al 2013;Brandt et al 2014;Samuel et al 2014;Raith et al 2016;Li et al 2018;George et al 2019;Han et al 2019;Talukdar et al 2019;Ratheesh-Kumar et al 2020). While the peak metamorphism of the Karimnagar Granulite Belt and Coorg block occurred in the Neoarchaean (c. 2600 Ma) and Mesoarchaean (c. 3000 Ma), respectively, the parts of the SGT (from Northern Granulite Terrane to PCSS) underwent peak metamorphism during the Archaean-Proterozoic boundary (c. 2700-2450 Ma).…”

Section: Introductionmentioning

confidence: 99%

Metamorphic evolution of the Sittampundi Layered Complex, India, during the Archaean–Proterozoic boundary: insight from pseudosection modelling and zircon U–Pb SHRIMP geochronology

Chatterjee

Lee

et al. 2022

Geol. Mag.

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In the Palghat–Cauvery Shear/Suture Zone of the Southern Granulite Terrane, the Sittampundi Layered Complex occurs as a mappable unit. The Sittampundi Layered Complex consists of mafic, ultramafic and anorthositic rocks with chromitite layers and has been interpreted as an arc/ophiolite complex that formed in an Archaean suprasubduction zone arc setting. In the Sittampundi Layered Complex, reddish-black metabasites occur as layers or boudins with a rim of amphibolite within anorthosite. The peak metamorphic assemblage of the metabasites is garnet + clinopyroxene + quartz + rutile ± plagioclase ± orthopyroxene, and symplectite consisting of amphibole and plagioclase formed around the garnet during retrograde metamorphism. The protolith of metabasite may have intruded in a suprasubduction zone arc setting during the late Neoarchaean (c. 2540–2520 Ma), and then underwent high-pressure granulite-facies peak metamorphism (900–800 °C and 11–14 kbar) in the early Palaeoproterozoic (c. 2460–2440 Ma), followed by amphibolite-facies metamorphism (550–480 °C and 5.5–4.5 kbar) in the middle Palaeoproterozoic (c. 1900–1850 Ma). The results obtained in this study, together with previous studies, indicate that: (1) the high-pressure granulite-facies metamorphism in the study area indicates that subduction occurred during the Archaean–Proterozoic boundary with a higher apparent average geothermal gradient (∼20–16 °C km−1) than the modern-day Earth, and (2) the apparent average geothermal gradient of the subduction zone was ∼29–14 °C km−1 during the Archaean–Proterozoic boundary, which was still too high to enter the realm of eclogite-facies metamorphism.

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Evolution of a Mesoarchean suprasubduction zone mantle wedge in the Dharwar Craton, southern India: Evidence from petrology, geochemistry, zircon U–Pb geochronology, and Lu–Hf isotopes

Cited by 12 publications

References 76 publications

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

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

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

Metamorphic evolution of the Sittampundi Layered Complex, India, during the Archaean–Proterozoic boundary: insight from pseudosection modelling and zircon U–Pb SHRIMP geochronology

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