Hostname: page-component-78c5997874-mlc7c Total loading time: 0 Render date: 2024-11-13T01:59:36.607Z Has data issue: false hasContentIssue false

The mineralogy of nepheline syenite complexes from the northern part of the Chilwa Province, Malawi

Published online by Cambridge University Press:  05 July 2018

Alan R. Woolley
Affiliation:
Department of Mineralogy, British Museum (Natural History), Cromwell Road, London SW7 5BD, UK
R. Garth Platt
Affiliation:
Department of Geology, Lakehead University, Thunder Bay, Ontario, Canada

Abstract

The mineralogy, including the accessory phases låvenite, rosenbuschite, and catapleiite, and consequent petrogenetic implications have been investigated for a group of four overlapping nepheline syenite complexes (Chikala, Chaone, Mongolowe, and Chinduzi) and for spatially associated silica-saturated and over-saturated perthosites, from the northern part of the Chilwa Alkaline Province, Malawi.

The complexes are thought to have formed by injection into high-level chambers of magma pulses genetically related to a common source magma at depth. Evidence for the source magma is preserved in salitic cores observed in the pyroxenes and a trend to more hedenbergite-rich compositions is believed to have formed by evolution of this magma. Subsequent trends of acmite enrichment followed magma injection into the higher-level chambers; the actual pyroxene trend associated with each individual complex is a function of the evolution attained by the source magma, oxidation potential, and perhaps even alkali activity. On the basis of such a two-stage model, the pyroxene data suggest emplacement of the Chaone and Mongolowe magmas somewhat earlier than that of Chikala, with the Chinduzi magma migrating even later.

Amphiboles and biotites are believed to have formed after high-level injection of the magmas. Their compositions broadly reflect the nature of the crystallizing pyroxenes in that magnesian hastingsitic hornblendes and more Mg-rich biotites are associated with more Mg-rich sodic pyroxenes, whereas katophorites and annite-rich micas are generally associated with sodic pyroxenes somewhat richer in hedenbergite. Sub-solidus crystallization in some of the complexes is represented by aegirine and magnesio-arfvedsonite. Nepheline compositions indicate broadly similar crystallization temperatures within the complexes, namely 950 to 750°C. Oxygen fugacities for these magmas obtained from biotite/annite compositions vary from 10−19 to 10−14 bars for this temperature range. Mineralogical data, particularly from pyroxenes and amphiboles, strongly suggest that the perthosites, spatially associated with the nepheline syenite complexes, are genetically unrelated.

Type
Silicate mineralogy
Copyright
Copyright © The Mineralogical Society of Great Britain and Ireland 1986

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Bloomfield, K. (1961) The age of the Chilwa Alkaline Province. Rec. Geol. Surv. of Malaw, 1, 95-100.Google Scholar
Bloomfield, K. (1965) The geology of the Zomba area. Bull. Geol. Sun. of Malawi, 16, 193 pp.Google Scholar
Cahen, L., and Snelling, N.J. (1966) The geology of equatorial Africa. North-Holland Publishing Company, Amsterdam. 195 pp.Google Scholar
Fudali, R.F. (1965) Oxygen fugacities of basaltic and andesitic magmas. Geochim. Cosmochim. Acta, 29, 1063-75.CrossRefGoogle Scholar
Garson, M.S. (1960) The geology of the Lake Chilwa area. Bull. Geol. Sun. of Nyasaland,, 12, 67 pp.Google Scholar
Garson, M.S. (1962) The Tundulu carbonatite ring-complex in southern Nyasaland. Mem. Geol. Surv. ofNyasaland, 2, 248 pp.Google Scholar
Garson, M.S. and Smith, W. Campbell (1958) Chilwa Island. Ibid. 1, 127 pp.Google Scholar
Hamilton, D.L. (1961) Nephelines as crystallization temperature indicators. J. Geol, 69, 321-9.CrossRefGoogle Scholar
Larsen, L.M. (1976) Clinopyroxenes and coexisting mafic minerals from the alkaline Ilimaussaq intrusion, South Greenland. J. Petrol, 17, 258-90.CrossRefGoogle Scholar
Leake, B.E. (1978) Nomenclature of amphiboles. Mineral. Mag, 42, 533-63.CrossRefGoogle Scholar
Mitchell, R.H., and Platt, R.G. (1978) Mafic mineralogy of ferroaugite syenite from the Coldwell alkaline complex, Ontario, Canada. J. Petrol, 19, 627-51.CrossRefGoogle Scholar
Mitchell, R.H., and Platt, R.G. (1982) Mineralogy and petrology of nepheline syenites from the Coldwell alkaline complex, Ontario, Canada. Ibid. 23, 186-214.CrossRefGoogle Scholar
Nash, W.P., and Wilkinson, J.F.G. (1970) Shonkin Sag laccolith, Montana. I. Mafic minerals and estimates of temperature, pressure, oxygen fugacity and silica activity. Contrib. Mineral. Petrol, 25, 241-69.CrossRefGoogle Scholar
Paul, A., and Douglas, R.W. (1965) Ferrous-ferric equilibrium in binary alkali silicate glasses. Phys. Chem. Glasse, 6, 207-11.Google Scholar
Platt, R.G., and Woolley, A.R. (1986) The mafic mineralogy of the peralkaline syenites and granites of the Mulanje complex, Malawi. Mineral. Mag, 50, 85-99.CrossRefGoogle Scholar
Wall, F., Williams, C.T., and Woolley, A.R. (in press) Zirconolite, chevkinite and other rare earth minerals from nepheline syenites and peralkaline granites and syenites of the Chilwa Alkaline Province, Malawi. Mineral Mag.51.Google Scholar
Powell, M. (1978) The crystallisation history of the Igdlerfigssalik nepheline syenite intrusion, Greenland. Lithos, 11, 99-120.CrossRefGoogle Scholar
Stephenson, D., and Upton, B.G.J. (1982) Ferromagnesian silicates in a differentiated alkaline complex: Kungnat Fjeld, South Greenland. Mineral Mag, 46, 283-300.CrossRefGoogle Scholar
Stillman, C.J., and Cox, K.G. (1960) The Chikala Hill syenite-complex of southern Nyasaland. Trans. Proc. Geol. Soc. S. Afr, 63, 99-117.Google Scholar
Tilley, C.E. (1954) Nepheline-alkali feldspar paragenesis. Am. J. Sci, 252, 65-75.CrossRefGoogle Scholar
Vail, J.R. and Maffick, D.I.J. (1965) The Mongolowe Hills nepheline-syenite ring-complex, southern Malawi. Geol. Surv. Malawi Rec, 3, 49-60.Google Scholar
Vail, J.R., and Monkman, L.J. (1960) A geological reconnaissance survey of the Chaone Hill ring complex, southern Nyasaland. Trans. Proc. Geol. Soc. S. Afr, 63, 119-35.Google Scholar
Vartiainen, H., and Woolley, A.R. (1976) The petrography, mineralogy and chemistry of the fenites of the Sokli carbonatite intrusion, Finland. Bull. Geol. Surv. Finland, 280, 1-87.Google Scholar
Woolley, A.R., and Garson, M.S. (1970) Petrochemical and tectonic relationship of the Malawi carbonatitealkaline province and the Lupata-Lebombo volcanics. In African magmatism and tectonic. (T. N. Clifford and I. G. Gass, eds.). Oliver and Boyd, Edinburgh. 237-62..Google Scholar
Woolley, A.R., and Garson, M.S. and Jones, G.C. (in press) The petrochemistry of the northern part of the Chilwa Alkaline Province, Malawi. Geol. Soc. London Spec. Publ. Google Scholar