Hostname: page-component-7479d7b7d-k7p5g Total loading time: 0 Render date: 2024-07-12T01:39:20.187Z Has data issue: false hasContentIssue false
  • English
  • Français

Convective fractionation during magnetite and hematite dissolution in silicate melts

Published online by Cambridge University Press:  05 July 2018

C. H. Donaldson
C. H. Donaldson*
Affiliation:
School of Geography and Geology, University of St. Andrews, Fife KY16 9ST, Scotland
Get access Rights & Permissions [Opens in a new window]

Abstract

Single crystals of magnetite and of hematite have been dissolved at atmospheric pressure in superheated melts in the systems CaO-MgO-Al2O3-SiO2 and CaO-Al2O3-SiO2, and in a basalt. The crystals were suspended in alumina crucibles containing ca 3.5 cm 3 of melt. Quenched run products were examined optically and by electron probe analysis to establish the distribution of Fe in the glassy charges. There is usually a concentration of Fe at the base of a run product, consistent with flow of dissolved matter from the crystal to the floor. One or more columns of brown, Fe-rich glass may extend from the underside of a relic crystal towards the floor. In CMAS run products, such columns typically extend this entire distance, whereas in the CAS and basalt run products, the columns are either detached from the crystal or do not reach the floor. In the CMAS melt (viscosity ~1 poise) there is apparently continuous release of Fe-bearing melt from around a dissolving crystal, whereas in the CAS and basalt melts (viscosities 7000 and 300 poise, respectively) release is intermittent. In CMAS run products the Fe content is usually greatest, in glass, at the base, and declines gradually upwards; in CAS and basalt runs the bottom of a crucible is occupied by discrete, sharply bounded pillows of Fetich glass, with only slight, or no, gradation in composition. Rising gas bubbles can elevate small blobs of the denser, Fe-bearing melt from around a dissolving crystal, and trains of bubbles in the CAS melt may guide this Fe-bearing melt, against gravity, to the surface of the charge. When the bubbles burst at the surface, this dense melt is left in an unstable location and releases diapirs which descend to the bottom of the crucible. In spite of the evidence that convective fractionation occurs in these haplomagmas and in the basalt, it remains to be demonstrated that it will occur during sidewall crystallization or during the growth of minerals in a cumulus mush to cause magmatic differentiation.

Keywords

fractionationmagnetitehematitesilicate meltsmagmatic differentiation
Type
Petrology and Geochemistry
Information
Mineralogical Magazine , Volume 57 , Issue 388 , September 1993 , pp. 469 - 488
Copyright
Copyright © The Mineralogical Society of Great Britain and Ireland 1993

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

Baines, W. D. and Turner, J. S. (1969) Turbulent buoyant convection from a source in a confined region. J. Fluid Mech., 37, 5180.Google Scholar
Bottinga, Y. and Javoy, M. (1990) MORB degassing: bubble growth and ascent. Chem. Geol., 81, 255–70.Google Scholar
Bottinga, Y. and Weill, D. (1970) Densities of liquid silicate systems calculated from partial molar volumes of oxide components. Amer. J. Sci., 269, 169–82.Google Scholar
Bottinga, Y. Kudo, A., and Weill, D. (1966) Some observations on oscillatory zoning and crystallization of magmatic plagioclase. Amer. Mineral., 51, 792806.Google Scholar
Brearley, M. and Scarfe, C. M. (1986) Dissolution rates of upper mantle minerals in an alkali basalt melt at high pressure: an experimental study and implications for ultramafic xenolith survival. J. Petrol., 27, 1157–82.Google Scholar
Brophy, J. G. (1990) Andesites from northeastern Kanaga Island, Aleutians. Implications for calc-alkaline fractionation mechanisms and magma chamber development. Contrib. Mineral. Petrol., 104, 568–81.Google Scholar
Campbell, I. H. and Turner, J. S. (1987) A laboratory investigation of assimilation at the top of a basaltic magma chamber. J. Geol., 95, 155–72.Google Scholar
Carruthers, J. R. (1976) Origins of convective temperature oscillations in crystal growth melts. J. Crystal Growth, 32, 1326.Google Scholar
Considine, D. M. (1989) Froth. In Science Encyclopedia. Van Nostrand, New York, 1243-4.Google Scholar
Coriell, S. R., Cordes, M. R., Boettinger, W. J., and Sekerka, R. F. (1980) Convective and interfacial instabilities during unidirectional solidification of a binary alloy. J. Crystal Growth, 49, 1328.Google Scholar
Deer, W. A., Howie, R. A., and Zussmann, J. (1964) Rock-Forming Minerals, Vol. 5. Longmans, London.Google Scholar
Donaldson, C. H. (1975) Calculated diffusion coefficients and the growth rate of olivine in a basalt magma. Lithos, 8, 163–74.Google Scholar
Donaldson, C. H. (1985) The rates of dissolution of olivine, plagioclase and quartz in a basalt melt. Mineral. Mag., 49, 683–93.Google Scholar
Donaldson, C. H. (1986) Mineral dissolution rates in a superheated basalt melt. Mat. Sci. Forum, 7, 267–74.Google Scholar
Donaldson, C. H. and Hamilton, D. L. (1987) Compositional convection and layering in a rock melt. Nature, 327, 413–15.Google Scholar
Donaldson, C. H. and Henderson, C. M. B. (1988) A new interpretation of round embayments in quartz crystals. Mineral. Mag., 52, 2734.Google Scholar
Duncan, R. A. and Richards, M. (1991) Hotspots, mantle plumes, flood basalts and true polar wander. Revs. Geophys., 29, 3150.Google Scholar
Grout, F. F. (1918) Two-phase convection in igneous magmas. J. Geol., 26, 481–99.Google Scholar
Helz, R. T. (1987) Differentiation behavior of the Kilauea Iki lava lake, Kilauea volcano, Hawaii: An overview of past and current work. In: Magmatic Processes: Physicochemical Principles (Mysen, B. O., ed.). Geochem. Soc. Spee. Publ., 1, 241-58.Google Scholar
Helz, R. T. Kirschenbaum, H., and Marinenko, J. W. (1989) Diapiric transfer of melt in Kilauea Iki lava lake, Hawaii: a quick, efficient process of igneous differentiation. Geol. Soc. Amer. Bull., 101, 578–94.Google Scholar
Hofmann, A. W. (1980) Diffusion in natural silicate melts; a critical review. In Physics of Magmatic Processes (Hargraves, R. B. ed.). Princeton Univ. Press, pp. 385417.Google Scholar
Hoover, J. D. (1989) Petrology of the Marginal Border Series of the Skaergaard intrusion. J. Petrol., 30, 399440.Google Scholar
Huppert, H. E., Sparks, R. S. J., Whitehead, J. A., and Hallworth, M. A. (1986) Replenishment of magma chambers by light inputs. J. Geophys. Res., 91, 6113–22.Google Scholar
Jebsen-Marwedl, H. (1956) ‘Faden’ im Glas eine Folge ‘dynactiven’ Verhaltens yon Schlieren. Glasteeh-nische Berichte, 29, 269–75.Google Scholar
Kerr, R. C. and Lister, J. R. (1991) The effects of shape on crystal settling and on the theology of magmas. J. Geol., 99, 457-67.Google Scholar
Kouchi, A. and Sunagawa, I. (1985) A model for mixing basaltic and dacitic magmas as deduced from experimental data. Contrib. Mineral. Petrol., 89, 1723.Google Scholar
Kuo, L.-C. and Kirkpatrick, R. J. (1985a) Kinetics of crystal dissolution in the system diopside-forsterite-silica. Amer. J. Sci., 285, 5191.Google Scholar
Kuo, L.-C. and Kirkpatrick, R. J. (1985b) Dissolution of marie minerals and its implication for the ascent velocities of peridotite-bearing basaltic magmas. J. Geol., 93, 691700.Google Scholar
Lawrence, M. and Birnie, S. (1989) A schlieren system in low-powered microscopy. Microscopy and Analysis, 49-54.Google Scholar
Leitch, A. M. (1990) Free convection in laboratory models. Earth Sci. Revs., 29, 369–83.Google Scholar
Levin, E. M., Robbins, C. R., and McMurdie, H. F. (1969) Phase diagrams for Ceramists. Amer. Ceram. Soc., Columbus, Ohio.Google Scholar
Loomis, T. P. (1982) Numerical simulations of crystallization processes of plagioclase in complex melts: the origin of multiple and oscillatory zoning in plagioclase. Contrib. Mineral. Petrol., 81, 219–29.Google Scholar
Mahood, G. A. and Cornejo, P. C. (1992) Evidence for ascent of differentiated liquids in silicic magma chamber found in granitic pluton. Trans. Roy. Soc. Edin., 83, 6370.Google Scholar
Martin, D. and Campbell, I. H. (1988) Laboratory modeling of convection in magma chambers; crystallization against sloping floors. J. Geophys. Res., 93, 7974–88.Google Scholar
Martin, D. Griffiths, R. W., and Campbell, I. H. (1987) Compositional and thermal convection in magma chambers. Contrib. Mineral. Petrol., 96, 465–75.Google Scholar
McBirney, A. R. (1980) Mixing and unmixing of magmas. J. Volcanol. Geoth. Res., 7, 357–71.Google Scholar
McBirney, A. R. and Noyes, R. M. (1979) Crystallization and layering of the Skaergaard intrusion. J. Petrol., 20, 487554.Google Scholar
McBirney, A. R. Baker, B. H., and Neilson, R. H. (1985) Liquid fractionation. 1. Basic principles and experimental simulations. J. Volcan. Geoth. Res., 24, 124.Google Scholar
Mo, X., Carmichael, I. S. E., Rivers, M., and Stebbins, J. (1982) The partial molar volume of Fe2O3 in multicomponent silicate liquids and the pressure dependence of oxygen fugacity in magmas. Mineral. Mag., 45, 273–45.Google Scholar
Morse, S. A. (1986) Thermal structure of crystallizing magma with two-phase convection. Geol. Mag., 123, 205–14.Google Scholar
Rice, A. R. (1981) Convective fractionation: a mech-anism to provide cryptic zoning (macrosegregation), layering, crescumulates, banded tufts and explosive volcanism in igneous processes. J. Geophys., Res., 86, 405–17.Google Scholar
Rosenberger, F. (1979) Fundamentals of Crystal Growth 1. Macroscopic Equilibrium and Transport Concepts. Springer-Vedag, Berlin, 519 pp.Google Scholar
Shaw, H. R. (1972) Viscosities of magmatic silicate liquids: an empirical method of prediction. Amer. J. Sci., 272, 870–93.Google Scholar
Sparks, R. S. J., Huppert, H. E., and Turner, J. S. (1984) The fluid dynamics of evolving magma chamber. Phil. Trans. R. Soc. Lond, A310, 511-34.Google Scholar
Sparks, R. S. J., Meyer, P., and Sigurdsson, H. (1980) Density variation amongst mid-ocean ridge basalts: impli-cations for magma mixing and the scarcity of primi-tive lavas. Earth Planet. Sci. Letts., 46, 419–30.Google Scholar
Stolper, E. and Walker, D. (1980) Melt density and the average composition of basalt. Contrib. Mineral. Petrol., 74, 712.Google Scholar
Tait, S. R., Huppert, H. E., and Sparks, R. S. J. (1984) The role of compositional convection in the formation of adcumulate rocks. Lithos, 17, 139–46.Google Scholar
Tait, S. R., and Jaupart, C. (1989) Compositional convection in viscous melts. Nature, 338, 571–4.Google Scholar
Tait, S. R., and Jaupart, C. (1990) Physical processes in the evolution of magmas. In: Reviews of Mineralogy 24. Modern Methods of Igneous Petrology (Nicholls, J. and Russell, J. K. eds.). Mineral. Soc. Amer. pp. 125-52.Google Scholar
Towers, H. and Chipman, J. (1957) Diffusion of Ca and Si in a lime-alumina slag. Trans. AIME, 209, 769–73.Google Scholar
Trial, A. F. and Spera, F. J. (1990) Mechanisms for the generation of compositional heterogeoeities in magma chambers. Geol. Soc. Amer. Bull., 102, 353-67.Google Scholar
Young, I. M., Greenwood, R. C., and Donaldson, C. H. (1988) Formation of the Eastern Layered Series of the Rhum complex, northwest Scotland. Can. Mineral., 26, 225–33.Google Scholar