The Mushandike granite: further evidence for 3.4 Ga magmatism in the Zimbabwe craton

M. H. DODSON; I. S. WILLIAMS; J. D. KRAMERS

doi:10.1017/S0016756801004939

Abstract

The conflict between independently published ages for the Mushandike Granite, Zimbabwe (2.92 ± 0.17 Ga and 3.45 ± 0.13 Ga) has been resolved in favour of the older age by SHRIMP U–Pb analyses of zircon. Two samples yield indistinguishable estimates of 3374 ± 7 and 3368 ± 11 Ma for the crystallization age of the magma. Together with published data from elsewhere in southern Zimbabwe, the results imply a widespread magmatic event at about 3.35 Ga. A single zircon core giving 3.46 Ga, together with the granite's previously measured Nd model age, suggests that the Mushandike magma could have incorporated remobilized basement similar to the c. 3.5 Ga Tokwe gneisses which crop out 30 km to the west. The published Rb–Sr and Pb–Pb datasets show evidence of late Archaean disturbance of Sr and Pb isotope systematics. In the absence of exposed contacts between the Mushandike granite and the neighbouring Mushandike stromatolitic limestone, the new U–Pb emplacement age suggests that the limestone is unconformable on the granite.

Crossref Citations

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Altermann, Wladyslaw 2001. The oldest fossils of Africa – a brief reappraisal of reports from the Archean. Journal of African Earth Sciences, Vol. 33, Issue. 3-4, p. 427.

Collerson, Kenneth D. Kamber, Balz S. and Schoenberg, Ronny 2002. Applications of accurate, high-precision Pb isotope ratio measurement by multi-collector ICP-MS. Chemical Geology, Vol. 188, Issue. 1-2, p. 65.

Bagai, Z. Armstrong, R. and Kampunzu, A.B. 2002. U–Pb single zircon geochronology of granitoids in the Vumba granite–greenstone terrain (NE Botswana):. Precambrian Research, Vol. 118, Issue. 3-4, p. 149.

Kamber, Balz S Bolhar, Robert and Webb, Gregory E 2004. Geochemistry of late Archaean stromatolites from Zimbabwe: evidence for microbial life in restricted epicontinental seas. Precambrian Research, Vol. 132, Issue. 4, p. 379.

Zhai, M. Kampunzu, A. B. Modisi, M. P. and Bagai, Z. 2006. Sr and Nd isotope systematics of Francistown plutonic rocks, Botswana: implications for Neoarchaean crustal evolution of the Zimbabwe craton. International Journal of Earth Sciences, Vol. 95, Issue. 3, p. 355.

Døssing, Lasse N. Frei, Robert Stendal, Henrik and Mapeo, Read B.M. 2009. Characterization of enriched lithospheric mantle components in ∼2.7Ga Banded Iron Formations: An example from the Tati Greenstone Belt, Northeastern Botswana. Precambrian Research, Vol. 172, Issue. 3-4, p. 334.

Rollinson, Hugh R. and Whitehouse, Martin 2011. The growth of the Zimbabwe Craton during the late Archaean: an ion microprobe U–Pb zircon study. Journal of the Geological Society, Vol. 168, Issue. 4, p. 941.

Abbott, Dallas H. Mooney, Walter D. and VanTongeren, Jill A. 2013. The character of the Moho and lower crust within Archean cratons and the tectonic implications. Tectonophysics, Vol. 609, Issue. , p. 690.

Prendergast, M.D. and Wingate, M.T.D. 2013. Zircon geochronology of late Archean komatiitic sills and their felsic country rocks, south-central Zimbabwe: A revised age for the Reliance komatiitic event and its implications. Precambrian Research, Vol. 229, Issue. , p. 105.

Kamber, Balz S. 2015. The evolving nature of terrestrial crust from the Hadean, through the Archaean, into the Proterozoic. Precambrian Research, Vol. 258, Issue. , p. 48.

Ranganai, Rubeni T. Whaler, Kathryn A. and Ebinger, Cynthia J. 2016. Aeromagnetic interpretation in the south-central Zimbabwe Craton: (reappraisal of) crustal structure and tectonic implications. International Journal of Earth Sciences, Vol. 105, Issue. 8, p. 2175.

Bolhar, Robert Hofmann, Axel Kemp, Anthony I.S. Whitehouse, Martin J. Wind, Sandra and Kamber, Balz S. 2017. Juvenile crust formation in the Zimbabwe Craton deduced from the O-Hf isotopic record of 3.8–3.1 Ga detrital zircons. Geochimica et Cosmochimica Acta, Vol. 215, Issue. , p. 432.

Sawada, Hikaru Mugandani, Ernest Tafumanei Sato, Tomohiko Sawaki, Yusuke Sakata, Shuhei Isozaki, Yukio and Maruyama, Shigenori 2019. Age constraints on the Palaeoproterozoic Lomagundi–Jatuli Event in Zimbabwe: Zircon geochronology of the Magondi Supergroup. Terra Nova, Vol. 31, Issue. 5, p. 438.

Hofmann, Axel and Chagondah, Godfrey 2019. Earth's Oldest Rocks. p. 855.

Dittrich, Thomas Seifert, Thomas Schulz, Bernhard Hagemann, Steffen Gerdes, Axel and Pfänder, Jörg 2019. Archean Rare-Metal Pegmatites in Zimbabwe and Western Australia. p. 23.

Jelsma, H.A. Nesbitt, R.W. and Fanning, C.M. 2021. Exploring our current understanding of the geological evolution and mineral endowment of the Zimbabwe Craton. South African Journal of Geology, Vol. 124, Issue. 1, p. 279.

Sawada, Hikaru Sawaki, Yusuke Sakata, Shuhei Ishikawa, Akira Muteta, Brian Isozaki, Yukio and Maruyama, Shigenori 2021. New geochronological constraints on the middle Archean Shurugwi greenstone belt toward an understanding of the crustal evolution of the Zimbabwe Craton. Journal of African Earth Sciences, Vol. 173, Issue. , p. 104021.

Hofmann, A. Kröner, A. Iaccheri, L.M. Wong, J. Geng, H. and Xie, H. 2022. 3.63 Ga grey gneisses reveal the Eoarchaean history of the Zimbabwe craton. South African Journal of Geology, Vol. 125, Issue. 1, p. 1.

Chaumba, Jeff B. and Mamuse, Antony 2023. Geochemistry of extremely modified chromites from the chrysotile asbestos-bearing Zvishavane Ultramafic Complex, south central Zimbabwe. Applied Earth Science: Transactions of the Institutions of Mining and Metallurgy, Vol. 132, Issue. 3-4, p. 281.

Basupi, Thembiso O. Tsunogae, Toshiaki Takahashi, Kazuki Takamura, Yusuke Mandingaisa, Prince and Tsutsumi, Yukiyasu 2023. Detrital zircon geochronology of quartzites from the Central Zone of the Limpopo Complex in southern Africa: Implications for different models and the timing of Zimbabwe Craton–Kaapvaal Craton amalgamation. Journal of African Earth Sciences, Vol. 202, Issue. , p. 104942.

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The Mushandike granite: further evidence for 3.4 Ga magmatism in the Zimbabwe craton

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The Mushandike granite: further evidence for 3.4 Ga magmatism in the Zimbabwe craton

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