Identifying Provenance of Archaean Basal Conglomerates: An Evidence from Sigegudda and Bababudan Conglomerate Quartzites, India

Geochemical characteristics of clastic sedimentary rocks deposited and later preserved in ancient supracrustal sequences of Archaean terrain are competent representation of their source rocks in provenance. These rocks usually sample a wide geographic area and bear signature of subsequently destroyed and dismembered terrains. In this study the quartz pebble conglomerate-quartz sandstone association of Sigegudda and Bababudan belt of western Dharwar craton (WDC), Southern India have been studied to understand the nature of their provenance. Both Sigegudda and Bababudan belt represent younger (2.8-2.6 Ga) greenstone sequences of WDC. They start with a prominent band of conglomerate-quartzite lying over Palaeo to Meso Archaean Peninsular Gneiss (3.35-3.29 Ga) with older Sargur greentone (3.35-3.28 Ga) enclaves along an unconformity. Here, we present a comprehensive provenance (mainly source rock characterization) study of major and trace element composition of low to moderately metamorphosed basal siliciclastics of the younger greenstone sequences of WDC. Chemically they are enriched in Th, U, HFSE (Hf, Nb, Zr) and depleted in Sc, Co, Cr and Eu content with elevated La/Sc and Th/Sc values depicting a differentiated felsic source. This is further supported by fractionated LREE (10.64 - 14.66), significant negative Eu anomaly (0.67 - 0.55) and nearly flat HREE indicating granitoid rocks as source. In La-Th-Cr/100 and La-Th-Sc triangular diagram, quartz arenite field overlap with the Peninsular Gneiss and plotted far away from the mafic-ultramafics of Sargur. The chemical index of alteration (CIA) values of arenites of Sigegudda (71) and Bababudan (75), Peninsular Gneisses (avg-50) and Sargur group (avg-30) implies their derivation from the underlying gneisses associated with a prolonged weathering. The presence of a thick conglomerate-quartz sandstone association with differently sized quartz in their framework and matrix, depicts the development of a stable craton in WDC during the Mesoarchaean. The geochemical results of conglomerate - quartzites along with their supported petrography strongly recommend the Peninsular gneiss as their provenance with prolonged erosion and sediment recycling.