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The petrology and geochemistry of the marginal and lower zones in the Clapham Trough, Eastern Bushveld Complex

Submitted in fulfilment of the requirements for a Master of Science degree in Geology, in the Department of Geosciences, University of the Witwatersrand, Johannesburg, South Africa.
2015 / This study undertook to re-evaluate the conventional historic interpretation that accepted the Marginal Zone as representative of the chill phase to the earliest emplacement of Lower Zone magmas. The Clapham Trough preserves a thick sequence of the Marginal Zone rocks, at least 220 m thick. Poor exposures and incomplete stratigraphy of the rock succession that occurs between the floor and the Marginal Zone rocks presented great limitations to earlier studies, and led earlier workers to accepting that the base of the Bushveld Complex is the Marginal Zone norite. This study presents results from the 692 m CH6 drilled core, which intersects the Marginal-Lower Zone boundary in the Clapham Trough.
The base of the CH6 drill core consists of melanorite (with less than 40 % cumulus plagioclase), which is conformable with the underlying, thick Basal Ultramafic Sequence (BUS, described in Wilson and Chunnett, 2010; and Wilson, 2012) separating the Marginal Zone rocks with the floor rocks of the Magaliesberg Formation. The amount of cumulus plagioclase in the Marginal Zone increases with increasing stratigraphic height such that the top units of the Marginal Zone are norite-leuconorites (typically 45-65 % cumulus plagioclase), bordering on anorthosite. The progressive changes in the modal variations led to the subdivision of the Marginal Zone norite to a basal Mafic Norite and a xenolith-bearing Shelter Norite. The latter is deemed a correlative of the Xenolithic Norite described at Olifants River Trough.
Coupled with the increasing amount of cumulus plagioclase, the An# increases with stratigraphic height. The An# fractionation trend is reversed from that of the co-existing orthopyroxene observed in the same interval (An63-74 vs. En81-70). The reversed An# compositions are an abnormal differentiation trend. The compositional disequilibrium
between co-existing orthopyroxene and plagioclase formed from in-situ crystallization with floatation of plagioclase, through convection, separating the cotectic phases.
All the data in the Marginal Zone show that these rocks have continuous fractionation trends with no interruptions. The Marginal Zone rocks are cumulus rocks that formed through fractional crystallization in a temporarily closed magma chamber. The present work showed unequivocally that the Marginal Zone is a product of differentiation of earlier emplacement of B1-magma, and cannot be representative of either a chill zone or composite sills. The appropriate (parental) liquid composition of the Marginal Zone formed after 30 % crystallization of the B1-magma. The postulated liquid composition is 6 wt. % MgO and 56.7 wt. % SiO2. The entire Marginal Zone succession would have formed from about 30-54 % crystallization of the B1-magma. The crystallization of the Marginal Zone was ended abruptly by the emplacement of a new batch of B1-magma, which must have mixed with the residual magma that must have ponded atop Marginal Zone cumulates after 54 % crystallization.
The mixing of the evolved residual magma and the primitive B1-magma formed the liquid postulated to be parental to the Lower Zone A (10.59 wt. % MgO and 57.10 wt. % SiO2). The Transitional Pyroxenite bears all the evidence of mixing between magmas of contrasting compositions, forming the 10-30 m gradational boundary unit between the Marginal Zone and Lower Zone A (correlative of the Lower Orthopyroxenite Subzone described at Olifants River Trough). The Lower Orthopyroxenite Subzone at the Clapham Trough is almost a mono-mineralic rock succession with generally constant orthopyroxene composition (En87-86), with the exceptions at marker norite horizons (En84-82; An83-81). The constant compositions observed in Lower Zone A are attributed to contemporaneous emplacement of new magma and differentiation, which maintained the composition of the parental magma.

Identiferoai:union.ndltd.org:netd.ac.za/oai:union.ndltd.org:wits/oai:wiredspace.wits.ac.za:10539/19360
Date20 January 2016
CreatorsZintwana, Masibulele P
Source SetsSouth African National ETD Portal
LanguageEnglish
Detected LanguageEnglish
TypeThesis
Formatapplication/pdf

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