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Alkali-feldspar and Fe-Ti oxide exsolution textures as indicators of the distribution and subsolidus effects of magmatic ‘water’ in the Klokken layered syenite intrusion, South Greenland

Published online by Cambridge University Press:  03 November 2011

Ian Parsons
Ian Parsons
Affiliation:
Department of Geology and Mineralogy, Marischal College, Aberdeen University, Aberdeen AB9 1AS, Scotland.
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Abstract

The layered syenites in the Klokken intrusion consist of horizons of fine-grained, granular-textured ferroaugite syenite showing inverted cryptic layering, interleaved with coarser, laminated, more fractionated hedenbergite syenite. Distribution of hydrous mafic phases indicates build-up of water in parallel with magmatic evolution, and druses and pegmatitic segregations in the laminated syenites are evidence for late development of a gas phase. Feldspar bulk compositions are close to the minimum on the Ab-Or binary, with An decreasing from An7 to An1 with fractionation, and normal zoning in cryptoperthite crystals. Feldspars in granular syenites are transparent coherent cryptoperthites or braid microperthites; An-content is probably the main control of fine-perthite coarseness. Laminated syenite feldspars are turbid, coarse patch microperthites with rare relics of braid textures. This non-coherent coarsening was caused by interactions between feldspars and water entrapped at magmatic temperatures which was retained within the original lithologies to low subsolidus temperatures. Fe-Ti oxides reflect this water distribution, with regular trellis ilmenite-titanomagnetite intergrowths in less fractionated rocks and ragged granule exsolution in more advanced syenites. The sharp change in exsolution textures at granular-laminated syenite boundaries implies steep water-gradients within these interleaved rock types. Water was unable to penetrate the granular layers and did not circulate freely in the cooling intrusion.

Keywords

PerthiteilmenomagnetiteGardarigneous fractionationhydrothermal fluids
Type
Research Article
Information
Earth and Environmental Science Transactions of The Royal Society of Edinburgh , Volume 71 , Issue 1 , 1980 , pp. 1 - 12
Copyright
Copyright © Royal Society of Edinburgh 1980

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References

Berger, G. W. 1975. 40Ar/39 Ar step heating of thermally over-printed biotite, hornblende and potassium feldspar from Eldora, Colorado. EARTH PLANET SCI LETT 26, 387408.CrossRefGoogle Scholar
Blaxland, A. B. & Parsons, I. 1975. Age and origin of the Klokken gabbro-syenite intrusion, South Greenland: Rb:Sr study. BULL GEOL SOC DENMARK 24, 2732.Google Scholar
Brown, W. L. & Willaime, C. 1974. An explanation of exsolution orientations and residual strain in cryptoperthites. In MacKenzie, W. S. & Zussman, J. (eds) The feldspars, 440–59. Manchester Univ. Press.Google Scholar
Buddington, A. F. & Lindsley, D. H. 1964. Iron-titanium oxide minerals and synthetic equivalents. J PETROL 5, 310–57.CrossRefGoogle Scholar
Czamanske, G. K. & Mihálik, P. 1972. Oxidation during magmatic differentiation. Finnmarka complex, Oslo area, Norway: Part 1, the opaque oxides. J PETROL 13, 493509.CrossRefGoogle Scholar
Duchesne, J.-C. 1972. Iron-titanium oxide minerals in the Bjerkrem-Sogndal massif, South-western Norway. J PETROL 13, 5782.CrossRefGoogle Scholar
Emeleus, C. H. & Smith, J. V. 1959. The alkali feldspars VI. Sanidine and orthoclase perthites from the Slieve Gullion area, Northern Ireland. AM MINERAL 44, 1187–209.Google Scholar
Emeleus, C. H. & Upton, B. G. J. 1976. The Gardar period in southern Greenland. In Escher, A. & Watt, W. S. (eds) Geology of Greenland, 152–81. Copenhagen: Gørnlands Geologiske Undersaøgelse.Google Scholar
Haggerty, S. E. 1971. High-Temperature oxidation of ilmenite in basalts. CARNEGIE INST WASHINGTON YEARBOOK 70, 165–76.Google Scholar
Halliday, A. N. & Mitchell, J. G. 1976. Structural, K-Ar and 40Ar-39 Ar age studies of adularia K-feldspars from the Lizard Complex, England. EARTH PLANET SCI LETT 29, 227–37.CrossRefGoogle Scholar
Martin, R. F. 1969. Hydrothermal synthesis of low albite. CONTRIB MINERAL PETROL 23, 323–39.CrossRefGoogle Scholar
Mason, R. A. 1979. The ordering behaviour of albite in aqueous solutions at 1 Kbar. CONTRIB MINERAL PETROL 68, 269–73.CrossRefGoogle Scholar
Parsons, I. 1978. Feldspars and fluids in cooling plutons. MINERAL MAG LONDON 42, 117.CrossRefGoogle Scholar
Parsons, I. 1979. The Klokken gabbro-syenite complex, South Greenland: Cryptic variation and origin of inversely graded layering. J PETROL 20, 653694.CrossRefGoogle Scholar
Parsons, I. in press. The Klokken gabbro-syenite complex, South Greenland: Quantitative interpretation of mineral chemistry. J PETROLGoogle Scholar
Parsons, I. & Boyd, R. 1971. Distribution of potassium feldspar polymorphs in intrusive sequences. MINERAL MAG LONDON 38, 295311.CrossRefGoogle Scholar
Patchett, P. J., van, Breemen O. & Martin, R. F. 1979. Sr isotopes and the structural state of feldspars as indicators of post-magnetic hydrothermal activity in continental dolerites. CONTRIB MINERAL PETROL 69, 6573.CrossRefGoogle Scholar
Powell, R. & Powell, M. 1977. Geothermometry and oxygen barometry using coexisting iron-titanium oxides. MINERAL MAG LONDON 41, 257–63.CrossRefGoogle Scholar
Smith, J. V. 1961. Explanation of strain and orientation effects in perthites. AM MINERAL 46, 1489–93.Google Scholar
Stewart, D. B. & Wright, T. L. 1974. Al/Si order and symmetry of natural alkali feldspars, and the relationship of strained cell parameters to bulk composition. BULL SOC FR MINERAL CRISTALLOGR 97, 356–77.Google Scholar
Taylor, H. P. Jr. 1974. The application of oxygen and hydrogen isotope studies to problems of hydrothermal alteration and ore deposition. ECON GEOL 69, 843–83.CrossRefGoogle Scholar
Taylor, H. P. Jr. & Forester, R. W. 1971. Low-O18 igneous rocks from the intrusive complexes of Skye, Mull and Ardnamurchan, Western Scotland. J PETROL 12, 465–98.CrossRefGoogle Scholar
Tuttle, O. F. & Bowen, N. L. 1958. Origin of granite in the light of experimental studies. MEM GEOL SOC AM 74.Google Scholar
Vincent, E. A. & Phillips, R. 1954. Iron-titanium oxide minerals in layered gabbros of the Skaergaard intrusion, East Greenland, Part 1. Chemistry and ore-microscopy. GEOCHIM COSMOCHIM ACTA 6, 126.CrossRefGoogle Scholar
Wager, L. R. & Brown, G. M. 1968. Layered igneous rocks. Edinburgh: Oliver & Boyd.Google Scholar
Wones, D. R. & Gilbert, M. E. 1969. The fayalite-magnetite-quartz assemblage between 600°C and 800°C. AM J SCI 267–A (Schairer vol.), 480–8.Google Scholar
Yund, R. A. 1975. Subsolidus phase relations in the alkali feldspars with emphasis on coherent phases. Miner Soc Amer Short Course Notes 2, Feldspar Mineralogy. Y1–Y57.Google Scholar