The geochemistry of Archaean plagioclase-rich granites as a marker of source enrichment and depth of melting

J.-F. Moyen; D. Champion; R. H. Smithies

doi:10.1017/S1755691009016132

Abstract

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In geochemical diagrams, granitoids define ‘trends’ that reflect increasing differentiation or melting degree. The position of an individual sample in such a trend, whilst linked to the temperature of equilibration, is difficult to interpret. On the other hand, the positions of the trends within the geochemical space (and not the position of a sample within a trend) carry important genetic information, as they reflect the nature of the source (degree of enrichment) and the depth of melting. This paper discusses the interpretation of geochemical trends, to extract information relating to the sources of granitoid magmas and the depth of melting.

%Applying this approach to mid-Archaean granitoids from both the Barberton granite–greenstone terrane (South Africa) and the Pilbara Craton (Australia) reveals two features. The first is the diversity of the group generally referred to as ‘TTGs’ (tonalites, trondhjemites and granodiorites). These appear to be composed of at least three distinct sub-series, one resulting from deep melting of relatively depleted sources, the second from shallower melting of depleted sources, and the third from shallow melting of enriched sources. The second feature is the contrast between the (spatial as well as temporal) distributions and associations of the granites in both cratons.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Moyen, Jean-François 2011. The composite Archaean grey gneisses: Petrological significance, and evidence for a non-unique tectonic setting for Archaean crustal growth. Lithos, Vol. 123, Issue. 1-4, p. 21.

Seixas, Luís Antônio Rosa David, Jean and Stevenson, Ross 2012. Geochemistry, Nd isotopes and U–Pb geochronology of a 2350Ma TTG suite, Minas Gerais, Brazil: Implications for the crustal evolution of the southern São Francisco craton. Precambrian Research, Vol. 196-197, Issue. , p. 61.

Mohan, M. Ram Singh, S.P. Santosh, M. Siddiqui, M.A. and Balaram, V. 2012. TTG suite from the Bundelkhand Craton, Central India: Geochemistry, petrogenesis and implications for Archean crustal evolution. Journal of Asian Earth Sciences, Vol. 58, Issue. , p. 38.

Ivanic, Timothy J. Van Kranendonk, Martin J. Kirkland, Christopher L. Wyche, Stephen Wingate, Michael T.D. and Belousova, Elena A. 2012. Zircon Lu–Hf isotopes and granite geochemistry of the Murchison Domain of the Yilgarn Craton: Evidence for reworking of Eoarchean crust during Meso-Neoarchean plume-driven magmatism. Lithos, Vol. 148, Issue. , p. 112.

van Hunen, Jeroen and Moyen, Jean-François 2012. Archean Subduction: Fact or Fiction?. Annual Review of Earth and Planetary Sciences, Vol. 40, Issue. 1, p. 195.

Mohan, M. Ram Piercey, Stephen J. Kamber, Balz S. and Sarma, D. Srinivasa 2013. Subduction related tectonic evolution of the Neoarchean eastern Dharwar Craton, southern India: New geochemical and isotopic constraints. Precambrian Research, Vol. 227, Issue. , p. 204.

Bagas, Leon Næraa, Tomas Kolb, Jochen Reno, Barry L. and Fiorentini, Marco L. 2013. Partial melting of the Archaean Thrym Complex of southeastern Greenland. Lithos, Vol. 160-161, Issue. , p. 164.

Srivastava, Rajesh K. 2013. Geochemistry of Proterozoic granitoids exposed between Dirang and Tawang, western Arunachal Himalaya, north-eastern India: petrogenetic and tectonic significance. International Journal of Earth Sciences, Vol. 102, Issue. 7, p. 2043.

Dantas, Elton Luiz de Souza, Zorano Sérgio Wernick, Eberhard Hackspacher, Peter Christian Martin, Hervé Xiaodong, Deng and Li, Jian-Wei 2013. Crustal growth in the 3.4–2.7Ga São José de Campestre Massif, Borborema Province, NE Brazil. Precambrian Research, Vol. 227, Issue. , p. 120.

Zhang, Chao Holtz, Francois Koepke, Jürgen Wolff, Paul Eric Ma, Changqian and Bédard, Jean H. 2013. Constraints from experimental melting of amphibolite on the depth of formation of garnet-rich restites, and implications for models of Early Archean crustal growth. Precambrian Research, Vol. 231, Issue. , p. 206.

Bédard, Jean H. Harris, Lyal B. and Thurston, Phillips C. 2013. The hunting of the snArc. Precambrian Research, Vol. 229, Issue. , p. 20.

Mohan, M. Ram Sarma, D. Srinivasa McNaughton, Neal J. Fletcher, Ian R. Wilde, Simon A. Siddiqui, Md. Alam Rasmussen, Birger Krapez, Bryan Gregory, Courtney J. and Kamo, Sandra L. 2014. SHRIMP zircon and titanite U-Pb ages, Lu-Hf isotope signatures and geochemical constraints for ∼2.56Ga granitic magmatism in Western Dharwar Craton, Southern India: Evidence for short-lived Neoarchean episodic crustal growth?. Precambrian Research, Vol. 243, Issue. , p. 197.

Bédard, Jean H. and Harris, Lyal B. 2014. Neoarchean disaggregation and reassembly of the Superior craton. Geology, Vol. 42, Issue. 11, p. 951.

Jayananda, M. Gireesh, R. V. Sekhamo, Kowete-U and Miyazaki, T. 2014. Coeval Felsic and Mafic Magmas in Neoarchean Calc-alkaline Magmatic Arcs, Dharwar Craton, Southern India: Field and Petrographic Evidence from Mafic to Hybrid Magmatic Enclaves and Synplutonic Mafic Dykes. Journal of the Geological Society of India, Vol. 84, Issue. 1, p. 5.

Santosh, M. Yang, Qiong-Yan Shaji, E. Tsunogae, T. Mohan, M. Ram and Satyanarayanan, M. 2015. An exotic Mesoarchean microcontinent: The Coorg Block, southern India. Gondwana Research, Vol. 27, Issue. 1, p. 165.

Janoušek, Vojtěch Moyen, Jean-François Martin, Hervé Erban, Vojtěch and Farrow, Colin 2016. Geochemical Modelling of Igneous Processes – Principles And Recipes in R Language. p. 27.

Nebel, O. Capitanio, F. A. Moyen, J.-F. Weinberg, R. F. Clos, F. Nebel-Jacobsen, Y. J. and Cawood, P. A. 2018. When crust comes of age: on the chemical evolution of Archaean, felsic continental crust by crustal drip tectonics. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, Vol. 376, Issue. 2132, p. 20180103.

Moyen, Jean-François and Laurent, Oscar 2018. Archaean tectonic systems: A view from igneous rocks. Lithos, Vol. 302-303, Issue. , p. 99.

Zhao, Tianyu Cawood, Peter A. Wang, Kai Zi, Jian-Wei Feng, Qinglai Nguyen, Quyen Minh and Tran, Dung My 2019. Neoarchean and Paleoproterozoic K-rich granites in the Phan Si Pan Complex, north Vietnam: Constraints on the early crustal evolution of the Yangtze Block. Precambrian Research, Vol. 332, Issue. , p. 105395.

Ahmad, Iftikhar Mondal, M. E. A. and Satyanarayanan, M. 2019. Geological Evolution of the Precambrian Indian Shield. p. 179.

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The geochemistry of Archaean plagioclase-rich granites as a marker of source enrichment and depth of melting

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This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

The geochemistry of Archaean plagioclase-rich granites as a marker of source enrichment and depth of melting

Abstract

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