Abstract
We have investigated the effect of Fe on the stabilities of carbonate (carb) in lherzolite assemblages by determining the partitioning of Fe and Mg between silicate (olivine; ol) and carbonates (magnesite, dolomite, magnesian calcite) at high pressures and temperatures. Fe enters olivine preferentially relative to magnesite and ordered dolomite, but Fe and Mg partition almost equally between disordered calcic carbonate and olivine. Measurement of K d (X carbFe X olMg /X olFe X carbMg ) as a function of Fe/ Mg ratio indicates that Fe−Mg carbonates deviate only slightly from ideality. Using the regular solution parameter for olivine W olFeMg of 3.7±0.8 kJ/mol (Wiser and Wood 1991) we obtain for (FeMg)CO3 a W carbFeMg of 3.05±1.50 kJ/mol. The effect of Ca−Mg−Fe disordering is to raise K d substantially enabling us to calculate W carbCaMg -W carbCaFe of 5.3±2.2 kJ/mol. The activity-composition relationships and partitioning data have been used to calculate the effect of Fe/Mg ratio on mantle decarbonation and exchange reactions. We find that carbonate (dolomite and magnesian calcite) is stable to slightly lower pressures (by 1 kbar) in mantle lherzolitic assemblages than in the CaO−MgO−SiO2(CMS)−CO2 system. The high pressure breakdown of dolomite + orthopyroxene to magnesite + clinopyroxene is displaced to higher pressures (by 2 kbar) in natural compositions relative to CMS. CO2. We also find a stability field of magnesian calcite in lherzolite at 15–25 kbar and 750–1000°C.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Anovitz LM, Essene EJ (1987) Phase equilibria in the system CaCO3−MgCO3−FeCO3. J Petrol 28:389–414
Berg GW (1986) Evidence for carbonate in the mantle. Nature 324:50–51
Berman RG (1988) Internally consistent thermodynamic data for minerals in the system Na2O−K2O−CaO−MgO−FeO−Fe2O3−Al2O3−SiO2−TiO2−H2O−CO2. J Petrol 29:445–522
Bickle MJ, Powell R (1977) Calcite-dolomite geothermometry for iron-bcaring carbonates: the Glockner area of the Tauern window, Austria. Contrib Mineral Petrol 59:281–292
Bottinga Y, Richet P (1981) High pressure and temperature equation of state and calculation of the thermodynamic properties of gaseous carbon dioxide. Am J Sci 281:615–660
Boyd FR, England JL (1960) Apparatus for phase-equilibrium measurements at pressures up to 50 kilobars and temperatures up to 1750° C. J Geophys Res 65:741–748
Brey G, Brice WR, Ellis DJ, Green DH, Harris KL, Ryabchikov ID (1983) Pyroxene-carbonate reactions in the upper mantle. Earth Planet Sci Lett 62:63–74
Canil D (1990) Experimental study bearing on the absence of carbonate in mantle-derived xenoliths. Geology 18:1011–1013
Canil D, Scarfe CM (1990) Phase transitions in Peridotite + CO2 systems to 12 GPa: implications for the origin of kimberlite and carbonate stability in the Earth's upper mantle. J Geophys Res 95 B10:15805–15816
Davidson PM, Lindsley DH (1985) Thermodynamic analyses of quadrilateral pyroxenes. Part II. Model calibration from experiments and applications to geothermometry. Contrib Mineral Petrol 91:390–404
Delaney JR, Muenow DW, Graham DG (1978) Abundance and distribution of water, carbon and sulphur in the glassy rims of submarine pillow basalts. Geochim Cosmochim Acta 42:581–594
Eggler DH (1975) Peridotite-carbonate relations in the system CaO−MgO−SiO2−CO2. Carnegie Inst Washington Yearb 74:59–64
Eggler DH (1976) Does CO2 cause partial melting in the lowvelocity layer of the mantle? Geology 4:69–72
Eggler DH, Kushiro I, Holloway JR (1976) Stability of carbonate minerals in a hydrous mantle. Carnegie Inst Washington Yearb 75:631–636
Eggler DH, Kushiro I, Holloway JR (1979) Free energies of decarbonation reactions at mantle pressures; 1. Stability of the assemblage forsterite-enstatite-magnesite in the system MgO−SiO2−CO2−H2O to 60 kbar. Am Mineral 64:288–293
Falloon TJ, Green DH (1989) The solidus of carbonated, fertile peridotite. Earth Planet Sci Lett 94:364–370
Ferry JM, Spear FS (1978) Experimental calibration of the partitioning of Fe and Mg between biotite and garnet. Contrib Mineral Petrol 66:113–117
Goldsmith JR, Heard HC (1961) Subsolidus phase relations in the system CaCO3−MgCO3. J Geol 69:45–74
Goldsmith JR, Newton RC (1969) P-T-X relations in the system CaCO3−MgCO3 at high temperatures and pressures. Am J Sci 267-A:160–190
Green HW, Radcliffe SV (1975) Fluid precipitates in rocks from the Earth's mantle. Geol Soc Am Bull 86:846–852
Hackler RT, Wood BJ (1989) Experimental determination of Fe and Mg exchange between garnet and olivine and estimation of Fe−Mg mixing properties in garnet. Am Mineral 74:994–999
Harrison WJ (1981) Partitioning of REE between minerals and coexisting melts during partial melting of a garnet lherzolite. Am Mineral 66:242–259
Hervig RL, Smith JV (1981) Dolomite-apatite inclusion in chromediopside crystal, Bellsbank kimberlite, South Africa. Am Mineral 66:346–349
Holland TJB, Powell R (1990) An enlarged and updated internally consistent thermodynamic dataset with uncertainties and correlations: the system K2O−Na2O−CaO−MgO−MnO−Fe2O3−Al2O3−TiO2−SiO2−C−H−O2. J Metamorphic Geol 8:89–124
Katsura T, Ito E (1990) Melting and subsolidus phase relations in the MgSiO3−MgCO3 system at high pressures: implications to evolution of the Earth's atmosphere. Earth Planet Sci Lett 99:110–117
Kawasaki T, Matsui Y (1983) Thermodynamic analyses involving olivine, orthopyroxene and garnet. Geochim Cosmochim Acta 47:1661–1679
Kushiro I, Satake H, Akimoto S (1975) Carbonate-sillicate reactions at high pressures and possible presence of dolomite and magnesite in the upper mantle. Earth Planet Sci Lett 28:116–120
Lindsley DH (1981) The formation of pigeonite on the join hedenbergite-ferrosilite at 11.5 and 15 kbar: experiments and a solution model. Am Mineral 66:1178–1182
Mäder UK, Berman RG (1991) An equation of state for carbon dioxide to high pressure and temperature. Am Mineral 76:1547–1559
McGetchin TR, Besancon JR (1973) Carbonate inclusions in mantle derived pyropes. Earth Planet Sci Lett 18:408–410
McSwiggen PL (1990) Carbonate solution model, calc-silicate phase equilibrium calculations and the metamorphism of the eastern penokean orogen, east-western Minncsota (unpubl). PhD thesis Univ Minnesota
Moore JG (1979) Vesicularity and CO2 in MORB. Nature 282:250–253
Moore JG, Batchelder JN, Cunningham CG (1977) CO2-filled vesicles in mid-ocean basalt. J Volcanol Geothermal Res 2:309–327
Nafziger RH, Muan A (1967) Equilibrium phasc compositions and thermodynamic properties of olivines and pyroxenes in the system MgO−FeO−SiO2. Am Mineral 53:1364–1385
Newton RC, Sharp WE (1975) Stability of forsterite+CO2 and its bearing on the role of CO2 in the mantle. Earth Planet Sci Lett 26:239–244
O'Ncill HStC, Wood BJ (1979) An experimental study of Fe−Mg partitioning between garnet and olivine and its calibration as a geothermometer. Contrib Mineral Petrol 70:59–70
Powell R, Holland TJB (1988) An internally consistent thermodynamic dataset with uncertainties and correlations. 3. Applications to geobarometry, worked examples and a computer program. J Metamorphic Geol 6:173–204
Reeder RJ, Nakajima Y (1982) The nature of ordering and ordering defects in dolomite. Phys Chem Miner 8:29–35
Reeder RJ, Wenk HR (1983) Structure refinements of some thermally disordered dolomites. Am Mineral 68:769–776
Roedder E (1965) Liquid CO2 inclusions in olivine-bearing nodules and phenocrysts in basalts. Am Mineral 50:1746–1782
Smith D (1987) Genesis of carbonate in pyrope from ultramafic diatremes on the Colorado Plateau, southwestern United States. Contrib Mineral Petrol 97:389–396
Takahashi E, Kushiro I (1983) Melting of a dry peridotite at high pressures and basalt magma genesis. Am Mineral 68:859–879
White BS, Wyllie PJ (1992) Solidus reactions in synthetic lherzolite−H2O−CO2 from 20–30 kbar, with applications to melting and metasomatism. J Volcanol Geothermal Res 50:117–130
Wiser NM, Wood BJ (1991) Experimental determination of activities in Fe−Mg olivine at 1400 K. Contrib Mineral Petrol 108:146–153
Woermann E, Rosenhauer M (1985) Fluid phases and the redox state of the Earth's mantle. Fortschr Mincral 63:263–349
Wood BJ, Banno S (1973) Garnet-orthopyroxene and orthopyroxene-clinopyroxene relationships in simple and complex systems. Contrib Mineral Petrol 42:109–124
Wyllie PJ (1977) Mantle fluid compositions buffered by carbonates in peridotite−CO2−H2O. J Geol 85:187–207
Wyllie PJ (1978) Mantle fluid compositons buffered in peridotite-CO2−H2O by carbonates, amphibole, and phlogopite. J Geol 86:687–713
Wyllie PJ, Huang WL (1976) Carbonation and melting reactions in the system CaO−MgO−SiO2−CO2 at mantle pressures with geophysical and petrological applications. Contrib Mineral Petrol 54:79–107
Wyllie PJ, Huang WL, Otto J, Byrnes AP (1983) Carbonation of peridotites and dacarbonation of siliceous dolomites represented in the sysem CaO−MgO−SiO2−CO2 to 30 kbar. Tectonophysics 100:359–388
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Dalton, J.A., Wood, B.J. The partitioning of Fe and Mg between olivine and carbonate and the stability of carbonate under mantle conditions. Contr. Mineral. and Petrol. 114, 501–509 (1993). https://doi.org/10.1007/BF00321754
Received:
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF00321754