Abstract
The phase relations of primitive magnesian andesites and basaltic andesites from the Mt. Shasta region, N California have been determined over a range of pressure and temperature conditions and H2O contents. The experimental results are used to explore the influence of H2O and pressure on fractional crystallization and mantle melting behavior in subduction zone environments. At 200-MPa H2O-saturated conditions the experimentally determined liquid line of descent reproduces the compositional variation found in the Mt. Shasta region lavas. This calc-alkaline differentiation trend begins at the lowest values of FeO*/MgO and the highest SiO2 contents found in any arc magma system and exhibits only a modest increase in FeO*/MgO with increasing SiO2. We propose a two-stage process for the origin of these lavas. (1) Extensive hydrous mantle melting produces H2O-rich (>4.5--6 wt% H2O) melts that are in equilibrium with a refractory harzburgite (olivine + orthopyroxene) residue. Trace elements and H2O are contributed from a slab-derived fluid and/or melt. (2) This mantle melt ascends into the overlying crust and undergoes fractional crystallization. Crustal-level differentiation occurs under near-H2O saturated conditions producing the distinctive high SiO2 and low FeO*/MgO characteristics of these calc-alkaline andesite and dacite lavas. In a subset of Mt. Shasta region lavas, magnesian pargasitic amphibole provides evidence of high pre-eruptive H2O contents (>10 wt% H2O) and lower crustal crystallization pressures (800 MPa). Igneous rocks that possess major and trace element characteristics similar to those of the Mt. Shasta region lavas are found at Adak, Aleutians, Setouchi Belt, Japan, the Mexican Volcanic Belt, Cook Island, Andes and in Archean trondhjemite--tonalite--granodiorite suites (TTG suites). We propose that these magmas also form by hydrous mantle melting.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
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 AT (1974) Evidence for a picritic, volatile-rich magma beneath Mt. Shasta, California. J Petrol 15:243–267
Anderson AT (1979) Water in some hypersthenic magmas. J Geol 87:509–531
Andersen DJ, Lindsley DH (1988) Internally consistent solution model for Fe--Mg--Mn oxides: Fe--Ti oxides. Am Mineral 73:714–726
Armstrong JT (1995) CITZAF—a package of correction programs for the quantitative electron microbeam X-ray analysis of thick polished materials, thin-films and particles. Microbeam Anal 4:177–200
Baker MB (1988) Evolution of lavas at Mt. Shasta volcano, N California: an experimental and petrologic study. PhD Thesis, MIT, Massachusetts
Baker MB, Grove TL, Price R (1994) Primitive basalts and andesites from the Mt. Shasta region, N California: products of varying melt fraction and water content. Contrib Mineral Petrol 118:111–129
Bence AE, Albee AL (1968) Empirical correction factors for the electron microanalysis of silicates and oxides. J Geol 76:382–403
Blatter DL, Carmichael ISE (1998) Plagioclase-free andesites from Zitacuaro (Michoacan), Mexico: petrology and experimental constraints. Contrib Mineral Petrol 132:121–138
Blatter DL, Carmichael ISE (2001) Hydrous phase equilibria of a Mexican high-silica andesite: a candidate for mantle origin? Geochim Cosmochim Acta 65:4043–4065
Boyd FR, England JL (1960) Apparatus for phase equilibrium studies at pressures up to 50 kilobars and temperatures up to 1,750 °C. J Geophys Res 65:741–748
Bryan WB, Finger LW, Chayes F (1969) Estimating proportions in petrographic mixing equations by least squares approximation. Science 163:926–927
Carmichael ISE, Lange RA, Luhr JF (1996) Quaternary minettes and associated volcanic rocks of Mascota, western Mexico: a consequence of plate extension above a subduction modified mantle wedge. Contrib Mineral Petrol 124:302–333
Christiansen RL, Kleinhampl FJ, Blakely RJ, Tuchek ET, Johnson FL, Conyac MD (1977) Resource appraisal of the Mt. Shasta wilderness study area, Siskiyou County, California. Open-file report 77-250, US Geol Surv, 538
Defant MJ, Drummond MS (1990) Derivation of some modern arc magmas by melting of young subducted lithosphere. Nature 347:662–665
Fuis GS, Zucca JJ, Mooney WD, Milkereit B (1987) A geologic interpretation of seismic-reflection results in northern California. Geol Soc Am Bull 98:53–65
Gaetani GA, Grove TL (1998) The influence of water on melting of mantle peridotite. Contrib Mineral Petrol 131:323–346
Gaetani GA, Grove TL (2003) Experimental constraints on melt generation in the mantle wedge. In: Eiler J, Abers G (eds) The subduction factory. Am Geophysical Union, Washington, DC (in press)
Gaetani GA, Grove TL, Bryan WB (1994) Experimental phase relations of basaltic andesite from Hole 839B under hydrous and anhydrous conditions. Proc Ocean Drill Program Sci Results 135:557–563
Gill JB (1981) Orogenic andesites and plate tectonics. Springer, Berlin Heidelberg New York
Green NL, Harry DL (1999) On the relationship between subducted slab age and arc basalt petrogenesis, Cascadia subduction system, North America. Earth Planet Sci Lett 171:367–381
Grove TL (1981) Use of FePt 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 (1993) Corrections to expressions for calculating mineral components. In: Origin of calc-alkaline series lavas at Medicine Lake Volcano by fractionation, assimilation and mixing and experimental petrology of normal MORB near the Kane fracture zone:22°--25°N, mid-Atlantic ridge. Contrib Mineral Petrol 114:422–424
Grove TL, Baker MB (1984) Phase equilibrium controls on the calc-alkaline vs. tholeiitic differentiation trends. J Geophys Res 89:3253–3274
Grove TL, Bence AE (1977) Experimental study of pyroxene--liquid interaction in quartz-normative basalt 15597. Proc Lunar Sci Conf 8:1549–1579
Grove TL, Juster TC (1989) Experimental investigations of low-Ca pyroxene stability and olivine--pyroxene--liquid equilibria at 1-atm in natural basaltic and andesitic liquids. Contrib Mineral Petrol 103:287–305
Grove TL, Kinzler RJ (1986) Petrogenesis of andesites. Annu Rev Earth Planet Sci 14:417–454
Grove TL, Donnelly-Nolan JM, Housh T (1997) Magmatic processes that generated the rhyolite of Glass Mountain, Medicine Lake volcano, N California. Contrib Mineral Petrol 127:205–223
Grove TL, Parman SW, Bowring SA, Price RC, Baker MB (2002) The role of an H2O-rich fluid component in the generation of primitive basaltic andesites and andesites from the Mt. Shasta region, N California. Contrib Mineral Petrol 142:375–396
Hamilton DL, Burnham CW, Osborn EF (1964) The solubility of water and the effects of oxygen fugacity and water content on crystallization in mafic magmas. J Petrol 5:21–39
Hays JF (1966) Lime-alumina-silica. Carnegie Inst Washington Yearbook 65:234–239
Hirose K (1997) Melting experiments on lherzolite KLB-1 under hydrous conditions and the generation of high-magnesian andesitic melts. Geology 25:42–44
Hirose K, Kawamoto T (1995) Hydrous partial melting of lherzolite at 1 GPa: the effect of H2O on the genesis of basaltic magmas. Earth Planet Sci Lett 133:463–473
Holloway JR, Burnham CW (1972) Melting relations of basalt with equilibrium water pressures less than total pressure. J Petrol 13:1--29
Ishizaka K, Carlson RW (1983) Nd--Sr systematics of the Setouchi volcanic rocks, southwest Japan: a clue to the origin of orogenic andesite. Earth Planet Sci Lett 64:327–340
Juster TC, Grove TL, Perfit MJ (1989) Experimental constraints on the generation of FeTi basalts, andesites and rhyodacites at the Galapagos Spreading Center, 85°W and 95°W. J Geophys Res 94:9251–9274
Kay RW (1978) Aleutian magnesian andesites: melts from subducted Pacific ocean crust. J Volcanol Geotherm Res 4:117–132
Kelemen PB (1990) Reaction between ultramafic rock and fractionating basaltic magma I. Phase relations, the origin of calc-alkaline magma series, and the formation of discordant dunite. J Petrol 31:51–98
Kelemen PB, Hirth JG, Shimizu N, Spiegelman M, Dick HBJ (1997) A review of melt migration processes in the adiabatically upwelling mantle beneath oceanic spreading ridges. Phil Trans R Soc Lond 355:283–318
Kinzler RJ, Donnelly-Nolan JM, Grove TL (2000) Late Holocene hydrous mafic magmatism at the Paint Pot Crater and Callahan Flows, Medicine Lake Volcano, N California and the influence of H2O in the generation of silicic magmas. Contrib Mineral Petrol 138:1--16
Kushiro I (1968) Compositions of magmas formed by partial melting of the Earth's upper mantle. J Geophys Res 73:619–634
Kushiro I (1969) The system forsterite--diopside--silica with and without water at high pressures. Am J Sci 267A:269–294
Kushiro I (1972) Effect of water on the compositions of magmas formed at high pressures. J Petrol 13:311–334
Kushiro I (1990) Partial melting of mantle wedge and evolution of island arc crust. J Geophys Res 95:15929–15939
Longhi J (1991) Comparative liquidus equilibria of hypersthene--normative basalts at low pressure. Am Mineral 76:785–800
Luhr JF, Carmichael ISE (1985) Jorullo Volcano, Michoacan, Mexico (1759–1774): the earliest stages of fractionation in calc-alkaline magmas. Contrib Mineral Petrol 90:142–161
Martin H (1987) Petrogenesis of Archean trondhjemites, tonalite and granodiorites from eastern Finland—major and trace element geochemistry. J Petrol 28:921–953
Miyashiro A (1974) Volcanic rock series in island arc and active continental margins. Am J Sci 274:321–355
Moore G, Carmichael ISE (1998) The hydrous phase equilibria (to 3 kbar) of an andesite and basaltic andesite from western Mexico: constraints on water content and conditions of phenocryst growth. Contrib Mineral Petrol 130:304–319
Müntener O, Kelemen PB, Grove TL (2001) The role of H2O during crystallization of primitive arc magmas under uppermost mantle conditions and genesis of igneous pyroxenites: an experimental study. Contrib Mineral Petrol 141:643–658
Shimoda G, Tatsumi Y, Nodha S, Ishizaka K, Jahn BM (1998) Setouchi high-Mg andesites revisited: geochemical evidence for melting of subducted sediments. Earth Planet Sci Lett 160:479–492
Sisson TW, Grove TL (1993a) Experimental investigations of the role of water in calc-alkaline differentiation and subduction zone magmatism. Contrib Mineral Petrol 113:143–166
Sisson TW, Grove TL (1993b) Temperature and H2O contents of low-MgO high-alumina basalts. Contrib Mineral Petrol 113:167–184
Sisson TW, Layne GD (1993) H2O in basalt and basaltic and andesite glass inclusions from four subduction-related volcanoes. Earth Planet Sci Lett 117:619–635
Smithies RB (2000) The Archean tonalite--trondhjemite--granodiorite (TTG) series is not an analogue of Cenozoic adakite. Earth Planet Sci Lett 182:115–125
Stern CR, Kilian R (1996) Role of subducted slab, mantle wedge and continental crust in the generation of adakites from the Andean Austral Volcanic Zone. Contrib Mineral Petrol 123:263–281
Tatsumi Y (1982) Origin of high-magnesian andesites in the Setouchi volcanic belt, southwest Japan, II. Melting phase relations at high pressures. Earth Planet Sci Lett 60:305–317
Tatsumi Y, Ishizaka K (1982) Origin of high-magnesian andesites in the Setouchi volcanic belt, southwest Japan, I. Petrographical and chemical characteristics. Earth Planet Sci Lett 60:293–304
Tatsumi Y, Sakuyama M, Fukuyama H, Kushiro I (1983) Generation of arc basalt magmas and thermal structure of the mantle wedge in subduction zones. Geophys Res 88:5815–5825
Thorpe RS (1982) Andesites: orogenic andesites and related rocks. Wiley, New York
Tormey DL, 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
Wagner TP, Donnelly-Nolan JM, Grove TL (1995) Evidence of hydrous differentiation and crystal accumulation in the low-MgO, high-Al2O3 Lake Basalt from Medicine Lake volcano, California. Contrib Mineral Petrol 121:201–216
Wilson D (1988) Tectonic history of the Juan de Fuca ridge over the last 40 million years. J Geophys Res 93:11863–11876
Yogodzinski GM, Kelemen PB (1998) Slab melting in the Aleutians: implications of an ion probe study of clinopyroxene in primitive adakite and basalt. Earth Planet Sci Lett 158:53–65
Yogodzinski GM, Kay RW, Volynets ON, Koloskov AV, Kay SM (1995) Magnesian andesite in the western Aleutian Komandorsky region: implications for slab melting and processes in the mantle wedge. Geol Soc Am Bull 107:505–519
Zhang Y-G, Frantz JD (2000) Enstatite--forsterite--water equilibria at elevated temperatures and pressures. Am Mineral 85:918–925
Acknowledgements
The authors thank J. Gill and J. Longhi for thoughtful reviews. This research was supported by National Science Foundation Grants EAR-9706214, EAR-0073766, and OCE-00001821. T.L.G. thanks A.N. Halliday and ETH, Zurich, for providing support as a Gastdozent during the preparation of this manuscript.
Author information
Authors and Affiliations
Corresponding author
Additional information
Editorial responsibility: J. Hoefs
Rights and permissions
About this article
Cite this article
Grove, T.L., Elkins-Tanton, L.T., Parman, S.W. et al. Fractional crystallization and mantle-melting controls on calc-alkaline differentiation trends. Contrib Mineral Petrol 145, 515–533 (2003). https://doi.org/10.1007/s00410-003-0448-z
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00410-003-0448-z