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The origin of igneous layering in the Nunarssuit syenite, South Greenland

Published online by Cambridge University Press:  05 July 2018

M. E. Hodson*
Affiliation:
Department of Geology and Geophysics, Grant Institute, University of Edinburgh, West Mains Road, Edinburgh EH9 3JW, UK

Abstract

The rhythmic modal layering in the Nunarssuit syenite has a vertical extent of >150 m and a lateral extent of >15 km. Individual layers average 20 cm thick and grade from a relatively melanocratic base into more leucocratic syenite over a distance of up to 5 cm. The major cumulus phases are alkali feldspar, ferro-salite/hedenbergite and fayalite. Two basic stratigraphic cycles have been identified in which faint modal layering becomes more pronounced up section, each cycle terminating in a thick melanocratic zone. Slumps, slump breccias, troughs, micro-rhythmic layering and one occurrence of crossed layers were observed.

Qualitative grain size analysis indicates no size sorting in the layers. Preliminary application of crystal size distribution theory to ferro-salite/hedenbergite and fayalite from the bases of individual layers gives results which may be interpreted as indicating a relative lack of coarse grains. If the layers were deposited from density currents it would be expected that the coarsest grains would be deposited close to the source of the currents. There is no evidence in the majority of the syenite that the cumulus pile underwent compaction during crystallization.

There was little, or no, primary chemical variation across individual layers. Whole-rock compositions and the ferro-salite/hedenbergite, fayalite, biotite and amphibole present in the syenites show a slight, but statistically significant, increase in the ratio Mg/(Mg+Fetotal), from the base up to the top of the layered succession.

A model is suggested in which successive magma layers become more ferroan towards the top of the chamber. Cooling is concentrated at the top of the chamber and layers of magma crystallize sequentially, the uppermost, ferroan layers first. As layers of magma cool and crystallize they sink, as crystal-melt plumes, to the bottom of the chamber where they source density currents from which layers are deposited.

Type
Research Article
Copyright
Copyright © The Mineralogical Society of Great Britain and Ireland 1998

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Footnotes

1

Present address: Macaulay Land Use Research Institute, Craigiebuckler, Aberdeen AB15 8QH, UK

References

Andersen, D.J. and Lindsley, D.H. (1988) Internally consistent solution models for Fe-Mg-Mn-Ti oxides: Fe-Ti oxide. Amer. Mineral., 73 714–26.Google Scholar
Anderson, J.G. (1974) The geology of Al<ngorssuaq, Northern Nunarssuit complex, South Greenland. Unpubl. PhD thesis, Univ. Aberdeen.Google Scholar
Bagdassarov, N. S. and Fradkov, A.S. (1993) Evolution of double diffusion convection in a felsic magma chambe. J. Volc. Geotherm. Res., 54 291308.CrossRefGoogle Scholar
Bak, P. and Chen, K. (1991) Self-organised criticality. Scientific American, 264, 2633.CrossRefGoogle Scholar
Barnes, S.J. (1986) The effect of trapped liquid crystallisation on cumulus mineral composition in layered intrusion. Contrib. Mineral. Petrol., 93, 524–31.CrossRefGoogle Scholar
Blaxland, A.B., Breemen, O. van, Emeleus, C.H. and Anderson, J.G. (1978) Age and origin of the major syenite centres of the Gardar: Rb–Sr studies. Geol. Soc. Amer. Bull., 78, 231–44.2.0.CO;2>CrossRefGoogle Scholar
Bottinga, Y., Weill, D.F., Richet, P. (1982) Density calculations for silicate liquids 1. Revised method for aluminosilicate compositions. Geochim. Cosmochim. Acta, 46, 909–19.CrossRefGoogle Scholar
Boudreau, A.E. (1987) Pattern formation during crystallisation and the formation of fine-scale layering. In: Origins of Igneous Layering (Parsons, I., ed.). NATO ASI Series C196, D. Reidel Publishing Company, Dordrecht, 453–71.CrossRefGoogle Scholar
Butterfield, A.W. (1980) Geology of the Western part of the Nunarssuit alkaline complex of south Greenland. Unpubl. PhD thesis, Univ. Aberdeen.Google Scholar
Cashman, K.V. and Ferry, J.M. (1988) Crystal size distribution in rocks and the kinetics and dynamics of crystallisation III. Metamorphic crystallisation. Contrib. Mineral. Petrol., 99, 401–15.CrossRefGoogle Scholar
Cashman, K.V. and Marsh, B.D. (1988) Crystal size distribution in rocks and the kinetics and dynamics of crystallisation II. Igneous crystallisation. Contrib. Mineral. Petrol., 99, 292305.CrossRefGoogle Scholar
Cawthorn, R.G. (1996) Layered Intrusions. Elsevier Science B.V. 531 pp.Google Scholar
Conrad, M.E. and Naslund, H.R. (1989) Modally-Graded Rhythmic Layering in the Skaergaard Intrusion. J. Petrol., 30, 251–69.CrossRefGoogle Scholar
Cox, K.G., Bell, J.D. and Pankhurst, R.J. (1979) The Interpretation of Igneous Rocks. George Allen and Unwin, 450 pp.CrossRefGoogle Scholar
Deer, W.A., Howie, R.A. and Zussman, J. (1966) An Introduction to the Rock-Forming Minerals. Longman 528 pp.Google Scholar
Emeleus, C.H. and Upton, B.G.J. (1976) The Gardar Period in southern Greenland. In: The Geology of Greenland (Escher, A. and Watt, W.S., eds). Grønls. Geol. Unders., Copenhagen, 153–81.Google Scholar
Ferguson, J. and Pulvertaft, T.C.R. (1963) Contrasted styles of igneous layering in the Gardar province of South Greenland. Spec. Pap. Mineral. Soc. Amer., 1, 1021.Google Scholar
Harris, C. and Grantham, G.H. (1993) Geology and petrogenesis of the Straumsvola nepheline syenite complex, Dronning Maud Land, Antarctica. Geol. Mag., 130, 513–32.CrossRefGoogle Scholar
Harry, W.T. and Pulvertaft, T.C.R. (1963) The Nunarssuit intrusive complex, S Greenland. Bull. Grønlands geol. Unders., 36.Google Scholar
Hodson, M.E. (1994) Igneous layering in the syenites of Nunarssuit and West Kungnat, South Greenland. Unpubl PhD thesis, Univ. Edinburgh.Google Scholar
Hodson, M.E. (1997) Post-crystallisation modification of the Nunarssuit and West Kûngnât layered syenites, South Greenland. Mineral. Mag., 61, 467–83.CrossRefGoogle Scholar
Hort, M., Marsh, B.D. and Spohn, T. (1993) An oscillatory nucleation model for igneous layering. Contrib. Miner. Petrol., 114, 425–40.CrossRefGoogle Scholar
Huppert, H.E. and Turner, J.S. (1991) Comments on ‘On convective style and vigor in sheet-like magma chambers’ by Bruce Marsh J. Petrol., 32, 851–4.CrossRefGoogle Scholar
Irvine, T.N. (1987 a) Processes involved in the formation and development of layered igneous rocks. Appendix II. In: Origins of Igneous Layering (Parsons, I., ed.). NATO ASI Series C196, D. Reidel Publishing Company, Dordrecht. 649–56.Google Scholar
Irvine, T.N. (1987 b) Layering and related structures in the Duke Island and Skaergaard intrusion: similarities, differences and origins. In: Origins of Igneous Layering (Parsons, I., ed.). NATO ASI Series C196, D. Reidel Publ ishing Company, Dordrecht. 185245.CrossRefGoogle Scholar
Kawasaki, T. and Ito, E. (1993) Fe-Mg partitioning between olivine and Ca-rich clinopy roxene: Implications for Fe-Mg mixing properties of Ca-rich clinopyroxene. Technical report of ISEI SerA No 54, 50 pp.Google Scholar
Marsh, B.D. (1988) Crystal size distribution in rocks and the kinetics and dynamics of crystallisation I: Theory. Contrib. Mineral. Petrol., 99, 277–91.CrossRefGoogle Scholar
Marsh, B.D. (1989) On convective style and vigor in sheet-like magma chambers. J. Pet., 30, 479530.CrossRefGoogle Scholar
Marsh, B.D. (1991) Reply [to H.E. Huppert and J.S. Turner]. J. Petrol., 32, 855–60.CrossRefGoogle Scholar
Marsh, B.D. and Maxey, (1985) On the distribution and separation of crystals in a convecting magma. J. Volc. Geoth. Res., 24, 94150.CrossRefGoogle Scholar
McBirney, A.R. and Noyes, R.M. (1979) Crystallisation and layering of the Skaergaard Intrusion. J. Petrol., 20, 487554.CrossRefGoogle Scholar
McDowell, S.D. and Wyllie, P.J. (1971) Experimental studies of igneous rock series: The Kûngnât syenite complex of Southwest Greenland. J. Geol., 79, 173–94.CrossRefGoogle Scholar
McNown, J.S. and Malaika, M. (1950) Effects of particle size on settling velocities at low Reynolds numbers. Trans. AGU, 31, 7482.CrossRefGoogle Scholar
Nekvasil, H. (1992) Ternary feldspar crystallisation in high temperature felsic magma. Amer. Mineral., 77, 592604.Google Scholar
Parsons, I. (1981) The Klokken gabbro-syenite complex, South Greenland: quantitative interpretation of mineral chemistry. J. Pet., 22, 233–60.CrossRefGoogle Scholar
Parsons, I. (ed), (1987) Origins of Igneous Layering. NATO ASI Series C196, D. Reidel Publishing Company, Dordrecht, 666 pp.CrossRefGoogle Scholar
Parsons, I. and Butterfield, A.W. (1981) Sedimentary features of Nunarssuit and Klokken syenites, S Greenland. J. Geol. Soc. Lond., 138, 289306.CrossRefGoogle Scholar
Raedeke, L.D. and McCallum, I.S. (1984) Investigations in the Stillwater Complex: Part II. Petrology and petrogenesis of the Ultramafic Series. J. Pet. 25 395420.CrossRefGoogle Scholar
Shaw, H.R. (1972) Viscosities of magmatic silicate liquids: An empirical method of prediction. Amer. J. Sci., 272, 870–93.CrossRefGoogle Scholar
Sparks, R.S.J. and Huppert, H.E. (1984) Density changes during the fractional crystallisation of basaltic magmas: fluid dynamic implications. Contrib. Mineral. Petrol., 85, 300–4.CrossRefGoogle Scholar
Sparks, R.S.J., Huppert, H.E., Koyaguchi, T. and Hallworth, M.A. (1993) Origin of modal and rhythmic igneous layering by sedimentation in a convecting magma chamber. Nature, 361, 246–9.CrossRefGoogle Scholar
Turner, J.S. and Campbell, I.H. (1986) Convection and mixing in magma chambers. Earth Science Reviews, 23, 255352.CrossRefGoogle Scholar
Tucker, M.E. (1981) Sedimentary petrology: An introduction. Blackwells scientific publications, 252 pp.Google Scholar
Upton, B.G.J. (1960) The alkaline igneous complex of Kûngnât Fjeld, South Greenland. Grøn. Geol. Und. Rap., 123.Google Scholar
Upton, B.G.J. (1974) The alkali province of SW Greenland. In: The Alkaline Rocks (Sørensen, H., ed.). Wiley, New York, 221–38.Google Scholar
Upton, B.G.J. and Emeleus, C.H. (1987) Mid- Proterozoic alkaline magmatism in S Greenland: The Gardar Province. In: Alkaline Igneous Rocks (Fitton, J.G., and Upton, B.G.J., eds). Geol. Soc. Spec. Publ., 30, 449–71.Google Scholar
Upton, B.G.J. and Fitton, J.G. (1985) Gardar dykes north of the Igaliko syenite complex, S Greenland. Grøn. Geol. Und. Rap., 127.Google Scholar
Upton, B.G.J., Emeleus, C.H., Parsons, I. and Hodson, M.E. (1996) Layered alkali igneous rocks of the Gardar province, South Greenland. In: Layered Intrusions (Cawthorn, R.G., ed.). Elsevier Science B.V., 331–63.CrossRefGoogle Scholar
Wadsworth, W.J. (1973) Magmatic sediments. Minerals Sci. Eng., 5, 2535.Google Scholar
Wager, L.R. and Brown, G.M. (1968) Layered Igneous Rocks. Oliver and Boyd, Edinburgh, 588 pp.Google Scholar
Waters, C. and Boudreau, A.E. (1997) A reevaluation of crystal-size distributions in chromite cumulates. Amer. Mineral., 81, 1452–9.CrossRefGoogle Scholar
Wilson, J.R., Menuge, J.F. and Pedersen, S. (1987) The southern part of the Fongen-Hyllingen layered mafic complex, Norway: Emplacement and crystallisation of compositionally stratified magma. In: Origins of Igneous Layering (Parsons, I., ed.). NATO ASI Series C196, D. Reidel Publishing Company, Dordrecht, 145–84.CrossRefGoogle Scholar