Abstract
At Medicine Lake Volcano, California, the compositional gap between andesite (57–62 wt.% SiO2) and rhyolite (73–74 wt.% SiO2) has been generated by fractional crystallization. Assimilation of silicic crust has also occurred along with fractionation. Two varieties of inclusions found in Holocene rhyolite flows, hornblende gabbros and aphyric andesites, provide information on the crystallization path followed by lavas parental to the rhyolite. The hornblende gabbros are magmatic cumulate residues and their mineral assemblages are preserved evidence of the phases that crystallized from an andesitic precursor lava to generate the rhyolite lavas. The andesitic inclusions represent samples of a parental andesite and record the early part of the differentiation history. Olivine, plagioclase and augite crystallization begins the differentiation history, followed by the disappearance of olivine and augite through reaction with the liquid to form orthopyroxene and amphibole. Further crystallization of the assemblage plagioclase, amphibole, orthopyroxene, magnetite, and apatite from a high-SiO2 andesite leads to rhyolite. This final crystallization process occurs on a cotectic that is nearly horizontal in temperature-composition space. Since a large amount of crystallization occurs over a limited temperature interval, a compositional gap develops between rhyolite and high SiO2 andesite.
Liquidus surfaces with shallow slopes in temperature-composition space are characteristic of several late-stage crystallization assemblages in the andesite to rhyolite compositional range. Experimentally produced plagioclase+ amphibole+orthopyroxene+magnetite and plagioclase+ augite+low-Ca pyroxene+magnetite cotectics have liquidus slopes that are nearly flat. At other calc-alkaline volcanic centers crystallization processes involving large compositional changes over small temperature intervals may also be important in the development of bimodal volcanism (i.e. the existence of a composition gap). At Mt. Mazama and Mt. St. Helens, USA and Aso Caldera and Shikotsu, Japan the amphibole-bearing assemblage was important. At Krakatau, Indonesia and Katmai, USA, an augite+orthopyroxene-bearing assemblage was important. In addition to its role in the production of a compositional gap between intermediate and rhyolitic lavas, the crystallization process increases the H2O content of the residual liquid. This rapid increase in residual liquid volatile content which results from the precipitation of a large proportion of crystalline solids may be an important factor among several that lead to explosive silicic eruptions.
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References
Albee AL, Ray L (1970) Correction factors for electron probe microanalysis of silicates, oxides, carbonates, phosphates and sulfates. Anal Chem 42:1408–1414
Anderson CA (1933) Volcanic history of Glass Mountain, northern California, Am J Sci 26:485–506
Anderson CA (1941) Volcanoes of the Medicine Lake Highland, California, University of California Department of Geological Sciences. Bulletin 25:347–442
Bacon CR (1983) Eruptive history of Mount Mazama and Crater Lake caldera, Cascade Range, USA. J Volcanol Geotherm Res 18:57–115
Bacon CR, Metz J (1984) Magmatic inclusions in rhyolites, contaminated basalts and compositional zonation beneath the Coso volcanic field, California. Contrib Mineral Petrol 85:346–365
Bence AE, Albee AL (1968) Empirical correction factors for the electron microanalysis of silicates and oxides. J Geol 76:382–403
Berman RG (1981) Differentiation of calc-alkaline magmas: Evidence from the Coquihalla volcanic complex, British Columbia. J Volcanol Geotherm Res 9:151–179
Bowen NL (1928) The Evolution of the Igneous Rocks, Princeton University Press
Carmichael ISE (1967) The iron-titanium oxides of salic volcanic rocks and their associated ferromagnesian silicates. Contrib Mineral Petrol 14:36–64
Clague DA (1978) The oceanic basalt-trachyte association: an explanation of the Daly gap. J Geol 86:739–743
DePaolo DJ (1981) Trace element and isotopic effects of combined wallrock assimilation and fractional crystallization. Earth Planet Sci Lett 53:189–202
Donnelly-Nolan JM (1983) Two ash-flow tuffs and the stratigraphy of Medicine Lake Volcano, Northern California Cascades (abstract). Geol Soc Am Abst with programs 15:330
Eichelberger JC (1975) Origin of andesite and dacite: evidence of mixing at Glass Mountain in California and at other circum-Pacific Volcanoes. Geol Soc Am Bull 86:1381–1391
Eichelberger JC (1980) Vesiculation of mafic magma during replenishment of silicic magma reservoirs. Nature 288:446–450
Eichelberger JC (1981) Mechanism of magma mixing at Glass Mountain, Medicine Lake Highland volcano, California, Johnston DA, Donnelly-Nolan J (eds) US Geological Survey circular 838:183–189
Fink JH, Pollard DD (1983) Structural evidence for dikes beneath silicic domes, Medicine Lake volcano, California. Geology 11:458–461
Finn C, Williams DL (1982) Gravity evidence for a shallow intrusion under Medicine Lake volcano, California. Geology 10:503–507
Ford CE, Russell DG, Craven JA, Fisk MR (1983) Olivine-liquid equilibria: Temperature, pressure and composition dependence of the crystal/liquid cation partition coefficients for Mg, Fe2+, Ca and Mn. J Petrol 24:256–265
Gerlach DC, Grove TL (1982) Petrology of Medicine Lake Highland volcanics: characterization of the end members of magma mixing. Contrib Mineral Petrol 80:147–159
Gill JB (1981) Orogenic Andesites and Plate Tectonics, Springer, Berlin Heidelberg New York
Green TH, Pearson NJ (1985) Experimental determination of REE partition coefficients between amphibole and basaltic to andesitic liquids at high pressure. Geochim Cosmochim Acta 49:1465–1468
Grove TL, Baker MB (1984) Phase equilibrium controls on the tholeiitic vs. calc-alkaline differentiation trends. J Geophys Res 89:3253–3274
Grove TL, Bryan WB (1983) Fractionation of pyroxene-phyric MORB at low pressure: an experimental study. Contrib Mineral Petrol 84:293–309
Grove TL, Baker MB, Donnelly-Nolan J (1984) The influence of crustal assimilation in the evolution of calc-alkaline series lavas (abstr.). Proceedings of the Conference on Open Magmatic Systems, Inst for the Study of Earth and Man, Dallas, TX, pp 57–59
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
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 highlands melt-rock. Proc 11th Lunar and Planet Sci Conf, pp 179–196
Heiken G (1978) Plinian-type eruptions in the Medicine Lake Highland, California and the nature of the underlying magma. J Volcanol Geotherm Res 2:1–16
Helz RT (1973) Phase relations of basalts in their melting range at\(P_{{\text{H}}_{\text{2}} {\text{O}}} \) kb as a function of oxygen fugacity. J Petrol 14:249–302
Helz RT (1976) Phase relations of basalts in their melting ranges at\(P_{{\text{H}}_{\text{2}} {\text{O}}} \)=5 kb. Part II. Melt compositions. J Petrol 17:139–193
Hildreth W (1981) Gradients in silicic magma chambers: Implications for lithospheric magmatism. J Geophys Res 86:10153–10192
Holloway JR, Burnham CW (1972) Melting relations of basalt with equilibrium water pressure less than total pressure. J Petrol 13:1–29
Irving AJ (1978) A review of experimental studies of crystal/liquid trace element partitioning. Geochim Cosmochim Acta 42:743–770
Katsui Y (1963) Evolution and magmatic history of some Krakatoan calderas in Hokkaido, Japan. J Fac Sci Hokkaido Univ, Ser 4. 11:631–650
Lewis JF (1973) Petrology of the ejected plutonic blocks of Soufriere Volcano, St. Vincent, West Indies. J Petrol 14:81–112
Lipman PW (1967) Mineral and chemical variations within an ash-flow sheet from Aso Caldera, Southwestern Japan. Contrib Mineral Petrol 16:300–327
Lipman PW, Norton DR, Taggart JE, Jr, Brandt EL, Engleman EL (1981) Compositional variations in 1980 magmatic deposits. US Geol Surv Prof Paper 1250:631–640
Luhr JF, Carmichael ISE (1980) The Colima volcanic complex, Mexico. I. Post-caldera andesites from Volcan Colima. Contrib Mineral Petrol 71:343–372
Mahood G, Hildreth W (1983) Large partition coefficients for trace elements in high silica rhyolites. Geochim Cosmochim Acta 47:11–30
McBirney AR, Nakamura Y (1974) Immiscibility in late stage magmas of the Skaergaard intrusion. Carnegie Inst Washington Yearb 73:348–352
Melson WG (1983) Monitoring the 1980–1982 eruptions of Mount St. Helens: Compositions and abundance of glass. Science 221:1387–1391
Mertzman SA (1977a) Recent volcanism at Schonchin and Cinder Buttes, Northern California. Contrib Mineral Petrol 61:231–243
Mertzman SA (1977b) The petrology and geochemistry of Medicine Lake volcano, Contrib Mineral Petrol 62:221–247
Mertzman SA (1982) K-Ar results for silicic volcanics from the Medicine Lake Highland, northeastern California — a summary. Isochron/West 34:3–7
Mertzman SA, Williams RJ (1981) Genesis of recent silicic magmatism in the Medicine Lake Highland, California: evidence from cognate inclusions found at Little Glass Mountain. Geochim Cosmochim Acta 45:1463–1478
Naney MT (1983) Phase equilibria of rock-forming ferromagnesian silicates in granitic systems. Am J Sci 283:993–1033
Naslund HR (1983) The effect of oxygen fugacity on liquid immiscibility in iron bearing silicate melts. Am J Sci 283:1034–1059
Nicholls IA (1971) Petrology of Santorini Volcano, Cyclades, Greece. J Petrol 12:67–119
Peacock MA (1931) The Modoc Lava Field, northern California. Geograph Rev 21:259–275
Philpotts, AR, Doyle CD (1983) Effect of magma oxidation state on the extent of silicate liquid immiscibility in a tholeiitic basalt. Am J Sci 283:967–986
Powers HA (1932) The lavas of the Modoc lava-bed quadrangle. Am Mineral 17:253–295
Ritchey JL (1980) Divergent magmas at Crater Lake, Oregon: Products of fractional crystallization and vertical zoning in a shallow, water-undersaturated chamber. J Volcanol Geotherm Res 7:373–386
Roedder E (1951) Low temperature liquid immiscibility in the system K2O-FeO-Al2O3-SiO2. Am Mineral 36:282–286
Rutherford MJ, Sigurdsson H, Carey S (1985) The May 18 eruption of Mount St. Helens: 1. Melt composition and experimental phase equilibria. J Geophys Res 90:2929–2947
Smith AL, Carmichael ISE (1968) Quaternary lavas from the southern Cascades, western USA. Contrib Mineral Petrol 19:212–238
Smith RL (1979) Ash flow magmatism. Geol Soc Am Spec Pap 180:5–27
Spencer KJ, Lindsley DH (1981) A solution model for coexisting iron-titanium oxides. Am Mineral 66:1189–1201
Spulber SD, Rutherford MJ (1983) The origin of rhyolite and plagiogranite in oceanic crust: An experimental study. J Petrol 24:1–25
Wager LR (1962) Igneous cumulates from the 1902 eruption of Soufriere, St., Vincent. Bull Volcanol 24:93–99
Watson EB, Green TH (1981) Apatite/liquid partition coefficients for the rare earth elements and strontium. Earth Planets Sci Lett 56:405–421
Watson EB, Naslund HR (1977) The effect of pressure on liquid immiscibility in the system K2O-FeO-Al2O3-SiO2-CO2. Carnegie Inst Washington Yearb 76:410–414
Williams H (1942) The geology of Crater Lake National Park, Oregon, with a reconnaissance of the Cascade Range south-ward to Mount Shasta, Carnegie Inst Washington Publ 540:162
Wyllie PJ (1963) Effects of changes in slope occurring on liquidus and solidus paths in the system diopside-anorthite-albite. Mineral Soc Am Spec Pap 1:204–212
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Grove, T.L., Donnelly-Nolan, J.M. The evolution of young silicic lavas at Medicine Lake Volcano, California: Implications for the origin of compositional gaps in calc-alkaline series lavas. Contr. Mineral. and Petrol. 92, 281–302 (1986). https://doi.org/10.1007/BF00572157
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DOI: https://doi.org/10.1007/BF00572157