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Archaean magmatism. NB- Arch ea n (US spelling) or Arch aea n (UK spelling). Why?. Somehow different from modern magmas Interesting to test our understanding of petrogenetic processes Not that rare, and good South African examples (Barberton) Economic interest
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Archaean magmatism NB- Archean (US spelling) or Archaean (UK spelling)
Why? • Somehow different from modern magmas • Interesting to test our understanding of petrogenetic processes • Not that rare, and good South African examples (Barberton) • Economic interest • Gold (large part of world’s gold + secondary deposits) • PGE bearing sulphides • Nickel • Department’s research interests
Two characteristic rock types • Komatiites = ultra-mafic, Mg-rich lavas • TTGs = Tonalites, Trondhejmites & Granodiorites • Link with Archaean geodynamic style?
75 % of the crust was formed at ca. 2.5 Ga The Archaean is a major crust-forming period
Earth’s heat production ►A 2- to 4-fold decrease from the Archaean to now
Effects of higher Archaean heat production? • Shape of convection • Partitioning of heat flux • Effects on the continents thermal structure and behaviour • Petrogenesis?
Shape of convection ? (Ra > 105) (Ra = 103 - 104) Ra = function of many things, including DT (or heat production)
Archaean dome-and-keel patterns Vertical tectonics (“sagduction”) Zimbabwe (2.7 Ga) Pilbara (3.5 Ga)
Bimodal Archaean terranes • Greenstone belts (commonly dominated by greenschist facies amphibolites) • Mafic and ultramafic (= komatiites) lavas • Some intermediate lavas (andesites) • Detrical sediments • Some chemical sediments (BIFs) or biogenic formations (stromatholites) • Gneissic « basement » or plutons • Late plutons
2.9 – 2.7 Ga granites 3.1 Ga granites & syenites Moodies Fig Tree Onverwacht Ca. 3.2 Ga TTG Ca. 3.4 Ga TTG « Ancient gneisses » (3.6 – 3.4 Ga)
1. Komatiites Viljoen, M. J. and R. P. Viljoen (1969). "The geology and geochemistry of the lower ultramafic unit of the Onverwacht group and a proposed new class of igneousrocks."Geological Society of South Africa Special Publication 2: 55-86. A truly South-African rock type!
Onverwacht group, BGB The original komatiites in Komatii formation (~1.5 km from type locality)
Structure of komatiites flows • Origin of komatiites • Komatiites and the Archaean mantle
Subdivision of komatiite flows (Arndt et al. 1977) Polysutured top Random spinifex Orientated spinifex parallel blades of spinifex solid subhedral olivine B4 Basal chill, polysutured
Chilled/brecciated top Subaquatic emplacement
Spinifex textured layer(s) • Random spinifex • Orientated spinifex • Plate spinifex Spinifex grass, Western Australia (Barnes 1990)
Origin of komatiites • High Mg contents require high degree of mantle melting (40-60 %) • This implies very high temperatures and fast rise
What are the implications of komatiites? • Probably formed in hot-spot like situations (difficult to arrive to > 1600° else) • Even though, this is hotted than modern hotspots • At least some parts of the Earth were very hot • At least part of the GSB formed from hotspots (intraplate situation)
3 groups of komatiites, from the shape of their HREE pattern (or Gd/Yb ratios) Role of garnet
Correlation with Al (and also Ca) • Al depleted (grp II) vs. Al-undepleted (grp. III) • Only grp I komatiites exist in the late Archaean
Early differenciation of the Earth mantle (completed at 3.80 Ga) • Deep origin of Late-Archaean komatiites (or locally non-differenciated bits of mantle?) • Maybe due to a cooler Earth, hot temperatures found only very deep?
2. TTG • Archaean TTG (Tonalite, Trondhjemites and Granodiorites) • ≈ grey gneisses (although in details, some TTGs are not grey gneisses and some grey gneisses are not TTG…)
Archaean grey gneisses Some relatively simple orthogneisses Stolzburg pluton (Barberton, 3.45 Ga)
The Sand River Gneisses Ca. 3.1 Ga TTG gneisses in Messina area, Limpopo Belt, South Africa (R. White, Melbourne, for scale)
However, the most common component of the grey gneisses is relatively constant