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Microlite-manganotantalite exsolution lamellae: evidence from rare-metal pegmatite, Karibib, Namibia

Published online by Cambridge University Press:  05 July 2018

J. R. Baldwin*
Affiliation:
Crustal Geodynamics Group, School of Geography and Geosciences, University of St Andrews KY16 9AL, UK
P. G. Hill
Affiliation:
Department of Geology and Geophysics, University of Edinburgh, Edinburgh EH9 3JW, UK
A. A. Finch
Affiliation:
Crustal Geodynamics Group, School of Geography and Geosciences, University of St Andrews KY16 9AL, UK
O. von Knorring
Affiliation:
School of Earth Sciences, University of Leeds, Leeds LS2 9JT, UK
G. J. H. Oliver
Affiliation:
Crustal Geodynamics Group, School of Geography and Geosciences, University of St Andrews KY16 9AL, UK
*
*Corresponding author

Abstract

We have analysed a rare occurrence of orange-brown manganotantalite lamellae (visible in hand specimen), intergrown with microlite [(Ca,Na)2(Ta,Nb)2(O,OH,F)7], aggregates of ferrotapiolite, bismuth minerals and apatite to understand more about the mechanisms of crystal growth and secondary modification in Ta-rich minerals. The intergrowth occurs within amblygonite/montebrasite nodules near the quartz core of the highly fractionated rare-metal Li/Be/Ta pegmatite at Rubicon, Karibib, Namibia. Electron microprobe analyses show that manganotantalite lamellae are variable in composition. Primary microlite (Ta2O5 82%, 1.97 Ta a.p.f.u.) forms the matrix mineral between the lamellae. Textural relations suggest an exsolution origin for the lamellae. Manganotantalite is represented by three generations: (1) primary late magmatic; (2) disequilibrium exsolution lamellae; and (3) subsolidus replacement. Crystallization commenced with primary microlite and likely simultaneous intergrowth between ferrotapiolite and a first generation of late-magmatic primary manganotantalite with low Ta (1.1—1.5 a.p.f.u.). On cooling this was followed by exsolution of manganotantalite lamellae, generation (2) with low—medium Ta (1.27—1.7 a.p.f.u.). The replacement of microlite by a highly fractionated late-stage melt rich in Mn2+, Ca2+ with low Na+ finally produces a third generation (3) of manganotantalite with high Ta (1.72—1.99 a.p.f.u.) at the contact with microlite. Native bismuth and bismutite cut across microlite and pseudomorph lamellae as a final hydrothermal replacement. Apatite is ubiquitous at the contact with amblygonite. The stability field of microlite may be extended by incorporation of CaTa2O6-rynersonite and Ca2Ta2O7 — idealized, components in solid solution. However, rynersonite-CaTa2O6 with distorted octahedra has some structural templates which are similar to the structure of pyrochlore (microlite). Hence, via the perovskite/pyrochlore analogy, hypothetical exsolution of manganotantalite-type structures may occur from a microlite (pyrochlore) host by solid-state diffusion via metastable rynersonite-type intermediates. Such a mechanism has the potential to explain the crystallographically controlled intergrowth textures and the compositional heterogeneity.

Type
Research Article
Copyright
Copyright © The Mineralogical Society of Great Britain and Ireland 2005

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References

Baldwin, J.R. (1989) Replacement phenomena in tantalum minerals in rare-metal pegmatites, South Africa and Namibia. Mineralogical Magazine, 53, 571581.CrossRefGoogle Scholar
Baldwin, J.R. (1993) Lithium and tantalum mineralzation from rare-element pegmatites in Southern Africa. Unpublished PhD thesis, University of St. Andrews, UK.Google Scholar
Baldwin, J.R. (2000) Fractionation trends, Rb, Cs, Ta and Mn in rare-element pegmatites in Namaqualand and Namibia. Journal of African Earth Sciences, 30 (4A), 89 (Special Abstract Issue for thel8th Colloquium on African Geology, Graz, Austria).Google Scholar
Baldwin, J.R, von Knorring, O. and Hill, P.G. (1997) Tantalum, bismuth and related minerals in lithium pegmatite, Karibib, Namibia. In: Intraplate Magmatism and Tectonics of Southern Africa and 17th Colloqium African Geology, Abstract volume, Zimbabwe.Google Scholar
Baldwin, J.R., Hill, P.G., von Knorring, O. and Oliver, G.J.H. (2000) Exotic aluminium phosphates, natro-montebrasite, brazilianite, goyazite, gorceixite and crandallite from rare-element pegmatites in Namibia. Mineralogical Magazine, 64, 11471164.CrossRefGoogle Scholar
Černý, P. (1989) Characterization of pegmatite deposits of tantalum. Pp. 195—339 in: Lanthanides, Tantalum and Niobium. (Moller, P. Černý, P. and Saupe, F. editors). Springer-Verlag, Berlin, Heidelberg.Google Scholar
Černý, P., Roberts, W.L., Ercit, T.S. and Chapman, R. (1985) Wodginite and associated oxide minerals from the Peerless pegmatite, Pennington County, South Dakota. American Mineralogist, 70, 10441049.Google Scholar
Černý, P., Ucakuwun, E.K. and Chapman, R. (1989a) A ferrotantalite-ferrotapiolite exsolution from Uganda. Neues Jahrbuch für Mineralogie Monatshefte, H3, 109120.Google Scholar
Černý, P., Chapman, R., Chakowsky, L.E. and Ercit, T.S. (1989b) A ferrotantalite-ferrotapiolite inter-growth from Spittal a.d. Drau, Carinthia, Austria. Mineralogy and Petrology, 41, 5363.CrossRefGoogle Scholar
Černý, P., Ercit, T.S. and Wise, M.A. (1992) The tantalite-tapiolite gap: natural assemblages versus experimental data. The Canadian Mineralogist, 30, 587596.Google Scholar
Ewing, R.C. (1975) Alteration of metamict, rare-earth, AB2O6-type Nb-Ta-Ti oxides. Geochimica et Cosmochimica Acta, 39, 521530.CrossRefGoogle Scholar
Hogarth, D.D. (1977) Classification and nomenclature of the pyrochlore group. American Mineralogist, 62, 403410.Google Scholar
Jahnberg, L. (1963) Crystal structure of orthorhombic CaTa2O6 . Acta Chemica Scandinavica, 71, 25482559.CrossRefGoogle Scholar
Keller, P. and von Knorring, O. (1989) Pegmatites at the Okatjimukuju farm, Karibib, Namibia. I. Phosphate mineral associations of the Clementine II pegmatite. European Journal of Mineralogy, 1, 567593.CrossRefGoogle Scholar
London, D. (1984) Experimental phase equilibria in the system LiAlSiO4-SiO2-H2O; A petrogenetic grid for lithium-rich pegmatites. American Mineralogist, 69, 9951004.Google Scholar
London, D. (1990) Internal differentiation of rare-element pegmatites, a synthesis of recent research. Geological Society of America, Special Paper, 246, 3550.CrossRefGoogle Scholar
London, D. (1992) The application of experimental petrology to the genesis and crystallization of pegmatite. The Canadian Mineralogist, 30, 499540.Google Scholar
London, D. and Burt, D.M. (1982) Lithium aluminosilicate occurrences in pegmatites and the lithium aluminosilicate phase diagram. American Mineralogist, 67, 483493.Google Scholar
Lumpkin, G.R. and Ewing, R.C. (1992) Geochemical alteration of pyrochlore group minerals: Microlite subgroup. American Mineralogist, 11, 179188.Google Scholar
Lumpkin, G.R., Chakoumakos, B.C. and Ewing, R.C. (1986) Mineralogy and radiation effects of microlite from the Harding pegmatite, Taos County, New Mexico. American Mineralogist, 71, 569588.Google Scholar
Novak, M. and Černý, P. (1998) Niobium-tantalum oxide minerals from complex granitic pegmatites in the Moldanubicum, Czech republic: primary and secondary compositional trends. The Canadian Mineralogist, 36, 659672.Google Scholar
Parsons, I. (1978) Feldspars and fluids in cooling plutons. Mineralogical Magazine, 42, 1 — 17.CrossRefGoogle Scholar
Pouchou, J. and Pichoir, F. (1991) Qualitative analysis of homogeneous or stratified microvolumes applying the modem ‘PAP'. Pp. 3175 in: Electron Probe Quantitative Analysis, (Heirich, K.F.J. and Newbury, D.E, editors). Plenum Press, New York, USA.CrossRefGoogle Scholar
Roering, C. (1961) The mode and emplacement of certain Li- and Be-bearing pegmatites in the Karibib district. SW Africa. Economic Geology Research unit, University of Witswatersrand, Johannesburg, South Africa, Information Circular 4.Google Scholar
Roering, C. and Gevers, T.W. (1962) Lithium and beryllium-bearing pegmatites in the Karibib district, South West Africa. Economic Geology Research unit, University of Witswatersrand, Johannesburg, South Africa, Information Circular 9.Google Scholar
Smith, D.A. (1965) The geology of the area around the Khan andSwakop rivers, South West Africa. Memoir 3, SW Africa Series, Geological Survey of South Africa, 113 pp.Google Scholar
van Wambeke, L. (1970) The alteration processes of the complex titano-niobo-tantalates and their consequences. Neues Jahrbuch für Mineralogie Abhandlungen, 112, 117149.Google Scholar
von Knorring, O. (1970) Mineralogical and geochemical aspects of pegmatites from orogenic belts of equatorial and southern Africa. Pp. 157184 in: African Magmatism and Tectonics, (Clifford, T.N. and Gass, I.G., editors). Oliver and Boyd, Edinburgh, UKGoogle Scholar
von Knorring, O. (1985a) Some mineralogical, geochemical and economic aspects of lithium pegmatites from the Karibib-Cape Cross pegmatite field in southwest Africa/Namibia. Communications of the Geological Survey of South West Africa/Namibia, 1, 7984.Google Scholar
von Knorring, O. (1985b) Niobium and tantalum minerals. Communications of the Geological Survey of South West Africa/Namibia, 1, 8588.Google Scholar
von Knorring, O. and Condliffe, E. (1984) On the occurrence of niobium and tantalum and other rare-elements in Meldon Aplite, Devonshire. Mineralogical Magazine, 48, 443448.CrossRefGoogle Scholar
von Knorring, O. and Condliffe, E. (1987) Mineralized pegmatites in Africa. Geological Journal, 22, 253–70.CrossRefGoogle Scholar
von Knorring, O. and Fadipe, A. (1981) On the mineralogy and geochemistry of niobium and tantalum in some granite pegmatites and alkali granites of Africa. Bulletin de Mineralogie, 104, 496507.CrossRefGoogle Scholar
Wise, M.A. and Černý, P. (1990) Primary compositional range and alteration trends of microlite from the Yellowknife pegmatite field, Northwest Territories, Canada. Mineralogy and Petrology, 43, 8398.CrossRefGoogle Scholar