Geology of the Eastern Barberton Greenstone Belt, South Africa: Early Deformation and the Role of Large Meteor Impacts

Abstract

The eastern Barberton Greenstone Belt (BGB) includes four stratigraphic and structural divisions: from northwest to southeast, the Mlumati, Manzimnyama, and Paulus Synclines and the Emlembe Belt. All are made up largely of sedimentary rocks of the Fig Tree Group separated by antiformal belts of sheared Onverwacht Group komatiitic rocks. Fig Tree rocks in the Mlumati and Manzimnyama Synclines are mostly chemically precipitated banded iron formation (BIF) and banded ferruginous chert (BFC) with a major siliciclastic unit, the Gelegela Grit, composed of quartz-poor (<5% monocrystalline quartz, Qm) volcaniclastic sandstone showing abundant ~3.445–3.455 Ga detrital zircons. The Paulus Syncline is dominated by shale containing in the upper half chert-clast conglomerate and sparse lithic sandstone (Qm<10%) but includes near the middle lenticular units up to unit 30 m thick of quartz-rich (Qm >50%) sandstone. The Emlembe Belt consists largely of chert-clast conglomerate and quartz-bearing (Qm = 10–50%) sandstone. The Paulus and Emlembe belts show detrital zircon age peaks at ~3.295–3.275 Ga and ~3.445–3.455 Ga. While exhibiting overall similar stratigraphic development and detrital zircon ages, Fig Tree rocks in these belts show contrasting compositions and sediment sources. They do not represent parts a single basin or fairway of sediment transport and deposition. Fig Tree siliciclastic rocks mark the first deformation, uplift, and erosion in the BGB. However, the thinness of Fig Tree strata, mostly less than 1000 m, and rapid facies changes argue that deformation involved local uplifts and small basins that accumulated thin sedimentary sequences. We suggest that early Fig Tree deformation is consistent with crustal disruption triggered by large meteor impacts, starting perhaps as early as ~3.277 Ga but certainly by ~3.260 Ga. The Fig Tree Group may record a cluster of impacts that fragmented and destabilized a long-lived crust followed during later or post-Fig Tree time by tectonic uplift and orogeny.