Physical volcanology and geochemistry of Palaeoarchaean komatiite lava flows from the western Dharwar craton, southern India: implications for Archaean mantle evolution and crustal growth

Abstract: Palaeoarchaean (3.38-3.35 Ga) komatiites from the Jayachamaraja Pura (J.C. Pura) and Banasandra greenstone belts of the western Dharwar craton, southern India were erupted as submarine lava flows. These high-temperature (1450-1550°C), low-viscosity lavas produced thick, massive, polygonal jointed sheet flows with sporadic flow top breccias. Thick olivine cumulate zones within differentiated komatiites suggest channel/conduit facies. Compound, undifferentiated flow fields developed marginal-lobate thin flows wi… Show more

“…The contact between layers is distinct, and interaction between dunite and pyroxenite and peridotite and pyroxenite are visible. The sharp contacts may be primarily the result of episodic injection of undifferentiated to slightly differentiated magma pulses that cooled and solidified without undergoing significant fractional crystallization [19]. Magnetite bands associated with chromite are also noticed in the layered sequences (Figure 2(b)).…”

Geochemistry of Layered Ultramafic Rocks in J.C. Pura Schist Belt, Dharwar Craton, Karnataka, India

“…The contact between layers is distinct, and interaction between dunite and pyroxenite and peridotite and pyroxenite are visible. The sharp contacts may be primarily the result of episodic injection of undifferentiated to slightly differentiated magma pulses that cooled and solidified without undergoing significant fractional crystallization [19]. Magnetite bands associated with chromite are also noticed in the layered sequences (Figure 2(b)).…”

Geochemistry of Layered Ultramafic Rocks in J.C. Pura Schist Belt, Dharwar Craton, Karnataka, India

“…Whereas, the Southern Indian Block (SIB) comprises the Dharwar-(including Southern Granulite Terrain), the Bastar-Singhbhum cratonic nuclei and the Eastern Ghats Belt (EGB) French et al, 2008) (Fig.2). These cratons are composed mostly of granites, gneisses and remnants of greenstone/schist belts of the Archaean age and the cratonic basins (Purana basins) of Proterozoic age (Jayananda et al, 2018(Jayananda et al, , 2016(Jayananda et al, , 2015Manikyamba et al, 2017;Saha and Mazumder, 2012;Chakraborty et al, 2010;Ramakrishna and Vaidyanadhan, 2008;Radhakrishna and Naqvi, 1986). Seismic studies and gravity modelling indicate the general crustal thickness of the Indian peninsular region to be about 35 km (Verma and Subrahmanyam, 1984;Kaila et al, 1979).…”

Geochronology, paleomagnetic signature and tectonic models of cratonic basins of India in the backdrop of Supercontinent amalgamation and fragmentation

“…Based on zircon Lu-Hf data with positive and negative εHf(t) values from ~3.9 to 1.5 and Hf depleted model ages (T DM ) of 3041-3366 Ma for the serpentinised dunite and ~0.2 to 2.0 and 2833-2995 Ma for the pyroxenite, the authors suggest that the magma was sourced from a depleted mantle and was contaminated with the ancient continental crust which is supported by the whole rock geochemistry. Based on the petrographic and geochemical characteristics, mantle plume emplacement in a marine environment was been suggested as a possible source for the genesis of J.C. Pura and Banasandra komatiites (Jayananda et al, 2016). To understand the evolution of Archean mantle, age and petrogenesis, Maya et al (2017) studied the major, trace and Sm-Nd isotopic systematics of the spinifex-textured komatiites from Mesoarchean Banasandra greenstone belt of the Sargur Group in the Dharwar Craton.…”

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