The lower Transvaal Supergroup cons

The lower Transvaal Supergroup consists of a mixed siliciclastic-carbonate ramp that grades upward into an extensive carbonate platform, overlain by banded ironformation. It was deposited on the Kaapvaal Craton between ~2.67 to ~2.46 Ga (Table 1; Armstrong et al., 1986; Barton et al., 1994; Walraven and Martini, 1995;Pickard, 2003; Dorland, 2004). Lower Transvaal Supergroup strata are extremely well preserved. Structural disruption is limited to gentle warping over most of the craton with locally steeper dips around the ~2.06 Ga Bushveld Complex (Walraven et al., 1990) and intense folding and faulting in the Kheis Belt and the Doornberg Fault Zone, which coincide with the western boundary of the Kaapvaal craton (Figure 1; Stowe, 1986; Beukes and Smit, 1987; Cornell et al., 1998). Postdepositional erosion limits the distribution of preserved strata, which does not reflect the extent and shape of the original depositional basin. The eastern half of the platform is traditionally called the Transvaal Basin (TB), whereas the western half is called the Griqualand West Basin (GB).Most outcrops experienced sub-greenschist facies metamorphism (Button, 1973b; Miyano and Beukes, 1984). However, amphibole is locally present due to Bushveld contact metamorphism in the Malmani Subgroup, and supergene alteration during late fluid flow produced local Pb-Zn, fluorite, and gold deposits in both the Malmani and Campbellrand subgroups (e.g., Martini, 1976; Clay, 1986; Duane et al., 1991; Tyler and Tyler, 1996; Duane et al., 2004). Early, fabric-retentive dolomite replaced most of the Malmani carbonates, particularly peritidal facies, which are also associated with chert replacement (Button, 1973b; Eriksson et al.,1975; Eriksson et al., 1976). However, significant amounts of the Campbellrand Subgroup still consist of limestone (Beukes, 1987; Sumner and Grotzinger, 2004). The Kaapvaal craton forms basement for the Transvaal Supergroup. It consists of diverse Archean granitoids, gneisses, and greenstone belts (see review in Poujol et al., 2003) with cratonic sediments as old as the 3.07 Ga Dominion Group, the >2837±5 Ma Mozaan Group, and the correlative Witwatersrand Supergroup (Armstrong et al., 1991; Gutzmer et al., 1999; Poujol et al., 2003). These are overlain by the 2740-2690 Ma Ventersdorp Supergroup (Armstrong et al., 1991; Schmitz and Bowring, 2003b), a succession of sedimentary and volcanic rocks including extensive flood basalts. Extrusion of the Ventersdorp Supergroup was associated with crustal extension and ultra high temperature metamorphism of the mantle lithosphere (Schmitz and Bowring, 2003a; b). Subsidence associated with slow cooling of the lithosphere likely provided accommodation space for the Transvaal Supergroup. A series of narrow basins filled with volcanics and siliciclastic sediments overlie cratonic basement where the Ventersdorp Supergroup is absent. They include the Derdepoort Belt, Tshwene-Tshwene Belt, Mogobane Formation, Buffelsfontein Group, Wachteenbeetje Formation, Bloempoort Formation, Godwan Group, and Wolkberg Group (Button, 1973a; Tyler, 1979; Hartzer 1989; Eriksson and Reczko, 1995; Catuneanu and Eriksson, 1999; Eriksson et al., 2001). These basins have been variously correlated to the Ventersdorp and lowermost Transvaal supergroups, and it is likely that they represent basins of various ages. The Derdepoort Belt contains felsic volcanics deposited at 2781±5 Ma (Wingate, 1998), which is older than the dated portions of the Ventersdorp Supergroup, which yields 2714±8 Ma zircons (Armstrong et al., 1991), although this age may not represent earliest Ventersdorp Supergroup volcanism (see discussion in Wingate, 1998). In contrast, volcanics in the Buffelsfontein Group are 2664±6 Ma, which is similar in age to the Schmidtsdrif Group, Transvaal Supergroup (Dorland, 2004). Based on the proportions of volcanic to non-volcanic deposits, it is reasonable to consider the Derdepoort and Tshwene-Tshwene belts equivalent to the Ventersdorp Supergroup, and the Buffelsfontein Group, Wachteenbeetje Formation, Bloempoort Formation, Godwan Group, and Wolkberg Group (“Wolkberg-equivalent units”) as associated with lowermost Transvaal Supergroup deposition until sufficient stratigraphic and age data are available to refine correlations. The Transvaal Supergroup unconformably overlies the Ventersdorp Supergroup, the Witwatersrand Supergroup, and granitic-greenstone basement (Figure 1; Button, 1973a; Beukes, 1977; 1979; Tyler, 1979; Clendenin et al., 1991; Els et al., 1995). The base of the Transvaal Supergroup in the TB is marked by 0-2 km of quartz arenite and shale forming the Wolkbergequivalent units (Figures 1 and 2; Button, 1973a; Tyler,
1979; Eriksson and Reczko, 1995; Hartzer, 1995;
Catuneanu and Eriksson, 1999). Isopach maps reveal large thickness variations in Wolkberg-equivalent units across the eastern Kaapvaal Craton related to paleotopography and differential subsidence (Button, 1973a; Tyler, 1979; Eriksson and Reczko, 1995; Hartzer, 1995), and deposition of at least the Buffelsfontein Group may overlap metamorphism in the Southern Marginal Zone of the Limpopo Belt (Barton and Van Reenen, 1992; Barton et al., 1995; Kreissig et al., 2001).
However, the Limpopo Belt contains abundant ~2.7 to ~2.6 Ga zircons, whereas detrital zircons in Wolkberg sandstones are dominantly older than ~2.9 Ga, suggesting that uplift of the Limpopo Belt did not provide sediment to the Wolkberg basin (Dorland, 2004). Thus, deposition and subsequent deformation of Wolkberg-equivalent units are unlikely to be related to Limpopo Belt uplift; rather deformation and subsidence may be due to residual extension after extrusion of the Ventersdorp Supergroup. Wolkbergequivalent sediments are unconformably overlain by the fluvial to shallow marine Black Reef Quartzite, which was broadly deposited over much of the craton with a sheet-like geometry (Eriksson et al., 2005). The Black Reef Quartzite grades upward into the Malmani carbonate platform (Button, 1973b; Clendenin et al., 1991; Els et al., 1995; Eriksson et al., 2005). In the GB, the base of the Transvaal Supergroup consists of mixed siliciclastic and carbonate rocks of the ~2.67 to ~2.65 Ga Schmidtsdrif Subgroup (Beukes, 1979; Dorland, 2004). The Schmidtsdrif Subgroup forms a sedimentary ramp that deepens southwestward and grades conformably upward into the carbonate platform of the Campbellrand Subgroup (Figure 2; Beukes, 1977; 1979; 1983a). The 2650-2500 Ma Campbellrand and Malmani subgroups are correlative and form an extensive carbonate platform (e.g., Button, 1976; Cheney, 1996; Martin et al., 1998). Preserved outcrops cover 190,000 km2 (Figure 1) and probably originally covered the entire Kaapvaal Craton, >600,000 km2 (Beukes, 1980; 1987). The platform is 1.5 to 2 km thick, with the predominantly peritidal facies in the north and east and deeper facies to the south and west (Figure 2; Beukes, 1987; Sumner and Grotzinger, 2004). Platform slope and basinal sediments are preserved near Prieska and are only about 500 m thick (Figures 1 and 2; Beukes, 1987; Sumner and Grotzinger, 2004). The ~2.5 to ~2.46 Ga Kuruman and Penge iron-formations conformably overlie the Campbellrand and Malmani subgroups, respectively (Figures 1 and 2). The Kuruman Iron Formation consists of deep water, microbanded iron formation (Beukes, 1984; Klein and Beukes, 1989), and the correlative lower Penge Iron Formation is lithologically similar. Both formed on a stable marine shelf below wave base and then shallowed to sea leve (Beukes, 1983b; Miyano and Beukes, 1997). Overall, Wolkberg-Schmidtsdrif to lower PengeKuruman deposition represents a genetically related package of sediments, whose accommodation space reflects evolution of the Kaapvaal craton after heating and thinning during Ventersdorp extrusion. They record the fluvial to marine transition during flooding of the craton, initiation of a long-lived, stable carbonate platform, drowning of that platform just prior to substantial iron-formation deposition, and subsequent shallowing back to sea level (e.g., Cheney, 1996; Martin et al., 1998; Eriksson et al., 2001).