Abstract
The use of non-regular solution models for silicate melts allows saturation temperatures to be calculated with an accuracy of±10 K for Mg and Fe, olivine or orthopyroxene components; and±20 K for Mn, Co and Ni components. This accuracy is comparable to that of the temperature measurement in the experiments with which the models are calibrated. The errors in the temperature calculation are less than a third of those associated with a regular solution model of mineral-melt equilibria. The values of thermodynamic properties predicted by these empirical solution models are larger than those found calorimetrically, but provide a better fit to the existing experimental data. The calculation of thermochemical properties of olivine and orthopyroxene species in both the crystalline and melt phases allows the calculation of mineral-melt\(K_{D_M /{\text{Mg}}}^{\alpha /L} \)s; the values calculated are within one standard error of those reported in the literature. Eruption temperatures calculated from the composition of Hawaiian tholeiite glasses range from 1135 to 1185°C, and are comparable to measured lava temperatures. These temperatures are lower than those calculated for Atlantic MORB confirming that extensive fractional crystallisation has occurred.
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References
Akella J, Williams RJ, Mullins O (1976) Solubility of Cr, Ti and Al in coexisting olivine, spinel and liquid at 1 atmosphere. Proc 7th Lunar Sci Conf, pp 1179–1194
Arndt NT (1977) Partitioning of nickel between olivine and ultrabasic komatiitic liquids. Carnegie Inst Washington Yearb 76:553–557
Beattie PD, Ford CE, Russell DG (1991) Partition coefficients for olivine-melt and orthopyroxene-melt systems. Contrib Mineral Petrol 109:212–224; see also erratum Contrib Mineral Petrol 114:288 (1993)
Beattie PD, Drake M, Jones J, Leeman W, Longhi J, McKay G, Nielsen R, Palme H, Shaw D, Takahashi E, Watson EB (1993) Terminology for trace element partitioning. Geochim Cosmochim Acta 57:1605–1606
Bender JF, Hodges FN, Bence AE (1978) Petrogenesis of basalts from the project FAMOUS area: experimental study from 0 to 15 kbar. Earth Planet Sci Lett 41:277–302
Bevington PR (1969) Data reduction and error analysis for the physical sciences. McGraw-Hill, New York
Bickle MJ, Ford CE, Nisbet EG (1977) The petrogenesis of peridotitic komatiites: evidence from high-pressure melting experiments. Earth Planet Sci Lett 37:97–106
Biggar GM (1984) The composition of diopside solid solutions, and of liquids, in equilibrium with forsterite, plagioclase, and in remelted rocks from 1 bar to 12 kbar. Mineral Mag 48:481–494
Biggar GM, O'Hara MJ, Peckett A, Humphries DJ (1971) Lunar lavas and the achondrites: petrogenesis of protohypersthene basalts in the maria lava lakes. Proc 2nd Lunar Sci Conf 617–643
Bird ML (1971) Distribution of trace elements in olivine and pyroxenes, an experimental study. PhD thesis, Univ Missouri, Rolla
Birle JD, Gibbs GV, Moore PB, Smith JV (1968) Crystal structure of natural olivines. Am Mineral 53:807–824
Boivin P (1980) Données expérimentales préliminaires sur la stabilité de la rhönite à 1 atmosphère: application aux gisements naturels. Bull Minéral 103:491–502
Bottinga Y, Weill DF (1972) The viscosity of magmatic silicate liquid, a model for calculation. Am J Sci 272:438–475
Bowen NL, Schairer JF (1935) The system MgO−FeO−SiO2. Am J Sci 29:151–217
Colson RO, Gust D (1989) Effects of pressure on partitioning of trace elements between low-Ca pyroxene and melt. Am Mineral 74:31–36
Colson RO, McKay GA, Taylor LA (1988) Temperature and composition dependencies of trace element partitioning: olivine/melt and low-Ca pyroxene/melt. Geochim Cosmochim Acta 52:539–553
Dearing KM (1985) Low-calcium pyroxene-melt equilibria at 1 bar: an experimental study in natural systems. PhD thesis, Univ Edinburgh
Deines P, Nafziger RH, Ulmer GC, Woerman E (1974) Temperature-oxygen fugacity tables for selected gas mixtures in the system C−H−O at one atmosphere total pressure. Bull Earth Miner Sci Exp Stn 88. Pa State Univ
Delano JW (1977) Experimental melting relations of 63545, 76015 and 76055. Proc 8th Lunar Sci Conf, pp 2097–2123
Drake MJ (1976) Plagioclase-melt equilibria. Geochim Cosmochim Acta 42:679–683
Drake MJ, Holloway JR (1981) Partitioning of Ni between olivine and silicate melt: the ‘Henry's Law problem’ reexamined. Geochim Cosmochim Acta 45:431–437
Elthon D, Scarfe CM (1984) High-pressure phase equilibria of high magnesia basalts and the genesis of primary oceanic basalts. Am Mineral 69:1–15
Garcia MO, Muenow DW, Aggrey KE (1989) Major element, volatile, and stable isotope geochemistry of Hawaiian submarine tholeiitic glasses. J Geophys Res 94 B8:10525–10538
Ghiorso MS, Carmichael IS, Rivers ML, Sack RO (1983) The Gibbs Free Energy of mixing of natural silicate liquids; an expanded regular solution approximation for the calculation of magmatic intensive variables. Contrib Mineral Petrol 84:107–145
Grove TL (1981) Use of PtFe alloys to eliminate the iron loss problem in 1 atmosphere gas mixing experiments: theoretical and practical considerations. Contrib Mineral Petrol 78:298–304
Grove TL, Beaty DW (1980) Classification, experimental petrology and possible volcanic histories of Apollo 11 high-K basalts. Proc 11th Lunar Sci Conf, pp 149–177
Grove TL, Bence AE (1977) Experimental petrology of pyroxene liquid interaction in quartz normative basalt 15 597. Proc 8th Lunar Sci Conf, pp 1549–1579
Grove TL, Gerlach DC, Sando TW (1982) Origin of calc-alkaline series lavas at Medicine Lake volcano by fractionation, assimilation and mixing. Contrib Mineral Petrol 80:160–182
Grove TL, Vaniman DT (1978) Experimental petrology of very low Ti (VLT) basalts. In: Merrill RB, Papike JJ (eds) Mare Crisium: the view from Luna 24. Pergamon, New York
Grover JE, Lindsley DH, Bence AE (1980) Experimental phase relations of olivine vitrophyres from breccia 14321: the temperature and pressure dependence of Fe−Mg partitioning for olivine and liquid in a highland melt rock. Proc 11th Lunar Sci Conf, pp 179–196
Hart SR, Davis KE (1978) Nickel partitioning between olivine and silicate melt. Earth Planet Sci Lett 40:203–219
Holloway JR, Wood BJ (1988) Simulating the Earth: experimental geochemistry. Unwin Hyman, Boston
Huebner JS, Lipin BR, Wiggins LB (1976) Partitioning of chromium between silicate crystals and melts. Proc 7th Lunar Sci Conf, pp 1195–1220
Irving AJ, Merrill RB, Singleton DE (1978) Experimental partitioning of rare earth elements and scandium among armalcolite, ilmenite, olivine, and mare basalt liquid. Proc 9th Lunar Sci Conf, pp 601–612
Killic A, Carmichael ISE, Rivers ML, Sack RO (1983) The ferricferrous ratio of natural silicate liquids equilibrated in air. Contrib Mineral Petrol 101:122–130
Kinzler RJ, Grove TJ, Recca SI (1990) An experimental study on the effect of temperature and melt composition on the partitioning of nickel between olivine and silicate melt. Geochim Cosmochim Acta 54:1255–1265
Leeman WP (1974) Petrology of basaltic lavas from the Snake River Plain, Idaho, and experimental determination of partitioning of divalent cations between olivine and basaltic liquids. Dissertation, Univ Oregon
Leeman WP, Lindstrom DJ (1978) Partitioning of Ni2+ between basaltic and synthetic melts and olivines—an experimental study. Geochim Cosmochim Acta 42:801–816
Leeman WP, Scheidegger KF (1977) Olivine/liquid distribution coefficients and a test for crystal-liquid equilibrium. Earth Planet Sci Lett 35:247–257
Leeman WP, Vitaliano CJ, Prinz M (1976) Evolved lavas from the Snake River Plain: Craters of the Moon National Monument, Idaho. Contrib Mineral Petrol 53:35–60
Lindstrom DJ (1976) Experimental study of the partitioning of the transition metals between clinopyroxene and coexisting silicate liquids. Dissertation Univ Oregon
Lindstrom DJ, Weill DF (1978) Partitioning of transition elements between diopside and co-existing silicate liquids. Geochim Cosmochim Acta 42:817–832
Longhi J, Walker D, Hays JF (1978) The distribution of Fe and Mg between olivine and lunar basaltic liquids. Geochim Cosmochim Acta 42:1545–1558
McKay GA, Weill DF (1977) KREEP petrogenesis revisited. Proc 8th Lunar Sci Conf, pp 2339–2355
Mah AD (1960) Thermodynamic properties of manganese and its compounds. US Bur Mines Rep Invest 5600
Matsui Y, Nishizawa O (1974) Iron(II)-magnesium exchange equilibrium between olivine and calcium-free pyroxene over a temperature range 800°C to 1300°C. Bull Soc Fr Mineral Crystallogr 97:122–130
Mysen BO, Virgo D, Kushiro I (1981) The structural role of aluminum in silicate melts—a Raman spectroscopic study at one atmosphere. Am Mineral 66:678–701
Nabelek PI (1980) Nickel partitioning between olivine and liquid in natural basalts: Henry's Law behaviour. Earth Plenet Sci Lett 48:293–302
Nafziger RH, Muan A (1967) Equilibrium phase compositions and thermodynamic properties of olivines and pyroxenes in the system MgO−“FeO”−SiO2. Am Mineral 52:1364–1385
Navrotsky A, Ziegler D, Oestrike R, Maniar P (1989) Calorimetry of silicate melts at 1773 K: measurement of enthalpies of fusion and of mixing in the systems diopside-anorthite-albite and anorthite-forsterite. Contrib Mineral Petrol 101:122–130
Nicholls J, Carmichael ISE (1972) The equilibrium temperature and pressure of various lava types with spinel- and garnet-peridotite. Am Mineral 57:941–959
Nielsen RL (1985) A method for the elimination of the compositional dependence of trace element distribution coefficients. Geochim Cosmochim Acta 49:1775–1779
Nielsen RL, Drake MJ (1979) Pyroxene-melt equilibria. Geochim Cosmochim Acta 43:1259–1273
Nielsen RL, Dungan MA (1983) Low pressure mineral-melt equilibria in natural anhydrous systems. Contrib Mineral Petrol 84:310–326
Peck DL (1978) Cooling and vesiculation of Alac lava lake, Hawaii. US Geol Surv Prof Pap 935-B
Press WH, Flannery BP, Teukolsky SA, Vettering WT (1986) Numerical recipes. Cambridge University Press, UK
Rhodes JM, Lofgren GE, Smith BP (1979) One atmosphere melting experiments on ilmentite basalt 12008. Proc 10th Lunar Sci Conf, pp 407–422
Russell DG (1984) Experimental and petrological studies of phenocryst assemblages in Scottish Permo-Carboniferous basaltic rocks. PhD thesis, Univ Edinburgh
Sack RO, Walker D, Carmichael ISE (1987) Experimental petrology of the alkalic lavas: constraints on cotectics of multiple saturation in natural basic liquids. Contrib Mineral Petrol 96:1–23
Schilling J-G, Sigurdsson H (1979) Thermal minima along the axis of the mid-Atlantic ridge. Nature 282:370–375
Schilling J-G, Zajac M, Evans R, Johnston K, White W, Devine JD, Kingsley R (1983) Petrologic and geochemical variations along the mid-Atlantic ridge from 29°N to 73°N. Am J Sci 283:510–586
Seifert S, O'Neill H St. C, Brey G (1988) The partitioning of Fe, Ni and Co between olivine, metal and basaltic liquid: an experimental and thermodynamic investigation, with application to the composition of the lunar core. Geochim Cosmochim Acta 52:603–616
Stebbins JF, Carmichael ISE (1984) The heat of fusion of fayalite. Am Mineral 69:292–297
Stebbins JF, Carmichael ISE (1989) The heat of fusion of fayalite: assessment of oxidation in calorimetric measurements. Eos Trans Am Geophys Union 62:1069
Stolper E (1977) Experimental petrology of eucrite meteorites. Geochim Cosmochim Acta 41:587–611
Stolper E (1980) A phase diagram for mid-ocean ridge basalts: preliminary results and implications for petrogenesis. Contrib Mineral Petrol 74:13–27
Takahashi E (1978) Partitioning of Ni2+, Co2+, Fe2+, Mn2+ and Mg2+ between olivine and silicate melts: compositional dependence of partition coefficient. Geochim Cosmochim Acta 42:1829–1844
Takahashi E (1980) Melting relations of alkali-olivine basalt to 30 kbar and their bearing on the origin of alkali basalt magmas. Carnegie Inst Yearb Washington 79:271–276
Toop GW, Samis CS (1962) Activities of ions in silicate melts. Trans Metall Soc AIME 224:878–887
Tormey DR, Grove TL, Bryan WB (1987) Experimental petrology of normal MORB near the Kane fracture zone: 22–25°N, mid-Atlantic ridge. Contrib Mineral Petrol 96:121–139
Walker D, Kirkpatrick RJ, Longhi J, Hays JF (1976) Crystallisation history of lunar picritic basalt sample 12002: phase-equilibria and cooling-rate studies. Geol Soc Am Bull 87:646–656
Walker D, Shibata J, DeLong SE (1979) Abyssal tholeiites from the Oceanographer fracture zone. Contrib Mineral Petrol 70:111–125
Watson EB (1977) Partitioning of manganese between forsterite and silicate liquids. Geochim Cosmochim Acta 41:1363–1374
Watson EB (1979) Calcium content of forsterite coexisting with silicate liquid in the system Na2O−CaO−MgO−Al2O3−SiO2. Am Mineral 64:824–829
Watson S, McKenzie DP (1991) Melt generation by plumes: a study of Hawaiian Volcanism. J Petrol 32:501–537
Weill DF, McKay GA (1975) The partitioning of Mg, Fe, Sr, Ce, Sm, Eu and Yb in lunar igneous systems and a possible origin of KREEP by equilibrium partial melting. Proc 6th Lunar Sci Conf, pp 1143–1158
Wiser NM, Wood BJ (1991) Experimental determination of activities in Fe−Mg olivine at 1400 K. Contrib Mineral Petrol 108:146–153
Wood BJ (1987) Thermodynamics of multicomponent systems containing several solid solutions. Rev Mineral 17:71–94
Wright TL, Peck DL (1978) Crystallization and differentiation of the Alae magma, Alae lava lake, Hawaii. US Geol Surv Prof Pap 935-B
Wright TL, Okamura RT (1977) Cooling and crystallization of tholeiitic basalt, 1965 Makaopuhi lava lake, Hawaii. US Geol Surv Prof Pap 1004
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Beattie, P. Olivine-melt and orthopyroxene-melt equilibria. Contr. Mineral. and Petrol. 115, 103–111 (1993). https://doi.org/10.1007/BF00712982
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DOI: https://doi.org/10.1007/BF00712982