Abstract
Refractory, primary liquids arising in various oceanic plate tectonic settings are characterized by high MgO, SiO2, Ca/Na, low TiO2 and generally low incompatible element abundances relative to primary liquids parental to MORB. We propose that the former melts segregate from upper mantle peridotite which has earlier been depleted by extraction of picritic melts which were parental to MORB. A compositional range in the ‘second-stage’ melts is expected, depending on the extent of previous depletion of the peridotite, the temperature and pressure of melt segregation, and the possible influence of volatile phases (C-H-O) present during melting.
An example of a second stage melt is of magnesian quartz tholeiite composition, identified from among the Upper Pillow Lavas, Troodos ophiolite, Cyprus. Experimental studies determine that this composition has appropriate liquidus phases to have segregated from depleted upper mantle peridotite at about 25 km, 1360° C leaving a harzburgite residue. The experimental studies are applied to interpretation of cooling histories and water contents of specific Upper Pillow Lavas. Magma batches are estimated to have contained 0.5–1.0% H2O. Picritic lavas quenched from olivine +liquid at <5 kb. Magnesian, pyroxene-phyric lavas exhibit intratelluric crystallization at ∼5 kb, 1270° C (Mg88 pigeonite and Mg89 orthopyroxene).
These and other second-stage melts will crystallize extremely refractory minerals identical to many found in cumulate sequences in ophiolites, in plutonic rocks dredged and drilled from ocean basins, and occurring as xenocrysts in ocean floor basalts. Multistage melting of upper mantle peridotite, with and without presence of water, reconciles some of the present difficulties in relating ophiolite and ocean floor basalt compositions, and is an important process in ocean crust formation in a variety of different oceanic settings (mid-ocean ridges, marginal basins, and island arcs).
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References
Basaltic Volcanism Project (1981) Basaltic volcanism on the terrestrial planets. Pergamon Press Inc., New York, p 1286
Bloomer SH (1983) Distribution and origin of igneous rocks from the landward slopes of the Mariana Trench: implications for its structure and evolution. J Geophys Res 88:7411–7428
Bryan WB, Moore JG (1977) Compositional variations of young basalts in the Mid-Atlantic Ridge rift valley near lat. 36°49′ N. Geol Soc Am Bull 88:556–570
Bryan WB, Thomson G, Frey FA, Dickey JS (1976) Inferred geologic settings and differentiation in basalts from the Deep Sea Drilling Project. J Geophys Res 81:4285–4304
Cameron WE (1985) Petrology and origin of primitive lavas from the Troodos ophiolite, Cyprus. Contrib Mineral Petrol 89:239–255
Cameron WE, Nisbet EG, Dietrich VJ (1979) Boninites, komatiites and ophiolitic basalts. Nature 280:550–553
Cameron WE, Nisbet EG, Dietrich VJ (1980) Petrographic dissimilarities between ophiolitic and ocean floor basalts. In: Panayiotou A (ed) Ophiolites. Geol Surv Dept, Nicosia, pp 182–192
Cameron WE, McCulloch MT, Walker DA (1983) Boninite petrogenesis: chemical and Nd-Sr isotopic constraints. Earth Planet Sci Lett 65:75–89
Christensen FNI, Salisbury MH (1975) Structure and constitution of the lower oceanic crust. Rev Geophys Space Phys 13:57–86
Crawford AJ (1980) A clinoenstatite-bearing cumulate olivine pyroxenite from Howqua, Victoria. Contrib Mineral Petrol 75:353–367
Dallwitz WB, Green DH, Thompson JE (1966) Clinoenstatite in a volcanic rock from the Cape Vogel Area, Papua. J Petrol 7:375–403
Dietrich V, Emmerman R, Oberhansli R, Puchelt H (1978) Geochemistry of basaltic and gabbroic rocks from the West Mariana Basin and the Mariana Trench. Earth Planet Sci Lett 39:127–144
Donaldson CH, Brown RW (1977) Refractory megacrysts and magnesium-rich melt inclusions within spinel in oceanic tholeiite: indicators of magma mixing and parental liquid compositions. Earth Planet Sci Lett 37:81–89
Drake MJ (1975) Plagioclase-melt equilibria. Geochim Cosmochim Acta 40:457–465
Duncan RA, Green DH (1980) The role of multi-stage melting in the formation of oceanic crust. Geology 8:22–26
Dungan MA, Long PE, Rhodes JM (1979) The petrography, mineral chemistry, and one-atmosphere phase relations of basalts from Site 395. In: Initial reports of the Deep Sea Drilling Project, vol 45. US Government Printing Office, Washington, DC, pp 461–477
Elthon D, Scarfe CM (1984) High pressure phase equilibria of a high magnesia basalt and the genesis of primary oceanic basalts. Am Mineral 69:1–15
England RN, Davies HL (1973) Mineralogy of ultramafic cumulates and tectonites from eastern Pacific. Earth Planet Sci Lett 17:416–425
Falloon TJ, Green DH (1986) Glass inclusions in magnesian olivine phenocrysts from Tonga — evidence for highly refractory parent magmas in the Tongan Arc. Earth Planet Sci Lett 81:95–103
Flower MFJ, Robinson PT, Schmincke U, Ohnmacht W (1977) Magma fractionation systems beneath the Mid-Atlantic Ridge at 36–37° N. Contrib Mineral Petrol 64:167–195
Frey FA, Bryan WB, Thompson G (1974) Atlantic ocean floor: geochemistry and petrology of basalts from Legs 2 and 3 of the Deep Sea Drilling Project. J Geophys Res 79:5507–5527
Frey FA, Dickey JS Jr, Thompson G, Bryan WB, Davies HL (1980) Evidence for heterogeneous primary MORB and mantle sources, NW Indian Ocean. Contrib Mineral Petrol 74:387–402
Gass IG (1958) Ultrabasic pillow lavas from Cyprus. Geol Mag 95:241–251
Gass IG, Smewing JD (1973) Intrusion, extrusion and metamorphism at constructive margins: evidence from the Troodos Massif, Cyprus. Nature 242:26–29
Gass IG, Lippard SJ, Shelton AW (eds) (1984) Ophiolites and oceanic lithosphere. Geol Soc Lond Spec Publ 13:1–413
Green TH (1972) Crystallization of calc-alkaline andesite under controlled high pressure hydrous conditions. Contrib Mineral Petrol 34:150–166
Green DH (1973) Conditions of melting of basanite magma from garnet peridotite. Earth Planet Sci Lett 17:456–465
Green DH, Ringwood AE (1967) The genesis of basaltic magmas. Contrib Mineral Petrol 15:103–190
Green DH, Hibberson WO, Jaques AL (1979) Petrogenesis of midocean ridge basalts. In: McElhinny MW (ed) The earth: its origin, structure and evolution. Academic Press, pp 265–290
Greenbaum D (1977) The chromitiferous rocks of the Troodos ophiolite complex, Cyprus. Econ Geol 72:1175–1194
Griffin BJ (1979) Energy-dispersive analysis system calibration and operation with TasSueds, an advanced interactive data-reduction package. Univ Tasmania Dep Geol Publ 343
Hamlyn PR, Bonatti E (1980) Petrology of mantle-derived ultramafics from the Owen F.Z., NW Indian Ocean: implications for the nature of the oceanic upper mantle. Earth Planet Sci Lett 48:65–79
Hawkins JW (1976) Petrology and geochemistry of basaltic rocks of the Lau Basin. Earth Planet Sci Lett 28:283–297
Hickey RL, Frey FA (1982) Geochemical characteristics of boninite series volcanics: implications for their source. Geochim Cosmochim Acta 46:2099–2115
Hodges FN, Papike JJ (1976) DSDP Site 334: magmatic cumulates from oceanic layer 3. J Geophys Res 81:4135–4151
Jaques AL (1981) Petrology and petrogenesis of cumulate peridotites and gabbros from the Marum ophiolite complex, northern Papua New Guinea. J Petrol 22:1–40
Jaques AL, Green DH (1980) Anhydrous melting of peridotite at 0–15 kb pressure and the genesis of tholeiitic basalts. Contrib Mineral Petrol 73:287–310
Jenner GA (1981) Geochemistry of high-Mg andesites from Cape Vogel, Papua New Guinea. Chem Geol 33:307–332
Jenner GA (1983) Petrogenesis of high-Mg andesites: an experimental and geochemical study with emphasis on high-Mg andesites from Cape Vogel, PNG. PhD thesis, University of Tasmania, Hobart
Juteau T, Whitechurch H (1980) The magmatic cumulates of Antalya (Turkey): evidence of multiple intrusions in an ophiolite magma chamber. In: Panayiotou A (ed) Ophiolites. Geol Surv Dep, Nicosia, pp 377–391
Kay RW, Senechal RG (1976) The rare earth geochemistry of the Troodos ophiolite complex. J Geophys Res 81:964–970
Kuroda N, Shiraki K (1975) Boninite and related rocks of Chichijima, Bonin Islands, Japan. Rep Fac Sci Shizuoka Univ 10:145–155
Langmuir CH, Bender JF, Bence AE, Hanson GN, Taylor SR (1977) Petrogenesis of basalts from the Famous area: Mid-Atlantic Ridge. Earth Planet Sci Lett 36:133–156
Lindsley DH (1983) Pyroxene thermometry. Am Mineral 68:477–493
McCulloch MT, Cameron WE (1983) Nd-Sr isotopic study of primitive lavas from the Troodos ophiolite, Cyprus: evidence for a subduction-related setting. Geology 11:727–731
Meijer A (1980) Primitive arc volcanism and a boninite series: examples from western Pacific island arcs. In: Hayes DE (ed) The tectonic and geologic evolution of southeast Asian seas and islands. Am Geophys Union Monogr 23:269–282
Meijer A, Anthony E, Reagan M (1982) Petrology of volcanic rocks from the fore-arc sites. In: Initial reports of the Deep Sea Drilling Project, vol 60, US Government Printing Office, Washington, DC, pp 709–730
Melson WG, Byerly GR, Nelen JA, O'Hearn T, Wright TL, Vallier T (1977) A catalogue of the major element chemistry of abyssal volcanic glasses. Smithsonian Contrib Earth Sci 19:31–60
Miyashiro A (1973) The Troodos ophiolitic complex was probably formed in an island arc. Earth Planet Sci Lett 19:218–224
Moores EM, Vine FJ (1971) The Troodos Massif, Cyprus, and other ophiolites as oceanic crust: evaluation and implications. Philos Trans R Soc London 268:443–466
Nicholls IA, Ringwood AE (1973) Effect of water on olivine stability in tholeiites and the production of silica-saturated magmas in the island arc environment. J Geol 81:289–300
O'Hara MJ (1968) Are ocean-floor basalts primary magmas? Nature 220:683–686
O'Hara MJ (1977) Geochemical evolution during fractional crystallization of a periodically refilled magma chamber. Nature 266:503–507
Pallister JS, Hopson CA (1980) Samail ophiolite plutonic suite: field relations, phase variation, cryptic variation and layering, and a model of a spreading ridge magma chamber. J Geophys Res 86:2593–2644
Pantazis TM, Panayiotou A, Gass I, Adamides N, Simonian K (1979) Field excursion guidebook. International Ophiolite Symposium, Nicosia, Cyprus. Geol Surv Dep Nicosia, p 142
Pearce JA (1975) Basalt geochemistry used to investigate the past tectonic environments on Cyprus. Tectonophys 25:41–67
Presnall DC, Hoover JD (1984) Composition and depth of origin of primary mid-ocean ridge basalts. Contrib Mineral Petrol 87:170–178
Presnall DC, Dixon JR, O'Donnell TH, Dixon SA (1979) Generation of mid-ocean ridge tholeiites. J Petrol 20:3–35
Price RC, Kennedy AK, Riggs-Sneeringer M, Frey FA (1986) Geochemistry of basalts from the Indian Ocean triple junction: implications for the generation and evolution of Indian Ocean ridge basalts. Earth Planet Sci Lett 78:379–386
Rautenschlein M, Jenner GA, Hertogen J, Hofmann AW, Kerrich R, Schminke H-U, White WM (1985) Isotopic and trace element composition of volcanic glasses from the Akaki Canyon, Cyprus: implications for the origin of the Troodos ophiolite. Earth Plant Sci Lett 75:369–383
Robinson PT, Melson WG, O'Hearn T, Schminke H-U (1983) Volcanic glass compositions of the Troodos ophiolite, Cyprus. Geology 11:400–404
Roeder PL, Emslie RF (1970) Olivine-liquid equilibrium. Contrib Mineral Petrol 29:275–289
Schminke H-U, Rautenschlein M, Robinson PT, Mehegan JM (1983) Troodos Extrusive series of Cyprus: a comparison with oceanic crust. Geology 11:405–409
Searle DL, Vokes FM (1969) Layered ultrabasic lavas from Cyprus. Geol Mag 106:515–530
Shibata T, DeLong SE, Walker D (1979) Abyssal tholeiites from the Oceanographer Fracture Zone. I. Petrology and fractionation. Contrib Mineral Petrol 70:89–102
Sigurdsson H, Schilling J-G (1976) Spinels in Mid-Atlantic Ridge basalts: chemistry and occurrence. Earth Planet Sci Lett 29:7–20
Simonian KO, Gass IG (1978) Arakapas fault belt, Cyprus: a fossil transform fault. Geol Soc Am Bull 89:1220–1230
Smewing JD, Potts PJ (1976) Rare-earth abundances in basalts and metabasalts from the Troodos Massif, Cyprus. Contrib Mineral Petrol 57:245–258
Smewing JD, Simonian KO, Gass IG (1975) Metabasalts from the Troodos Massif, Cyprus: genetic implication deduced from petrography and trace element geochemistry. Contrib Mineral Petrol 51:49–64
Stolper EM (1980) A phase diagram for mid-ocean ridge basalts: preliminary results and implications for petrogenesis. Contrib Mineral Petrol 74:13–27
Sun S-S, Nesbitt RW (1979) Geochemical regularities and genetic significance of ophiolitic basalts. Geology 6:689–693
Tatsumi Y (1981) Melting experiments on a high magnesium andesite. Earth Planet Sci Lett 54:357–365
Thy P, Brooks CK, Walsh JN (1985) Tectonic and petrogenetic implications of major and rare earth element chemistry of Troodos glasses, Cyprus. Lithos 18:165–178
Wood DA (1979) Dynamic partial melting: its application to the petrogenesis of basalts erupted in Iceland, the Faeroe Islands, the Isle of Skye (Scotland) and the Troodos Massif (Cyprus). Geochim Cosmochim Acta 43:1031–1046
Wyllie PJ (1979) Magmas and volatile components. Am Mineral 64:469–500
Yoder HS, Tilley CE (1962) Origin of basalt magmas: an experimental study of natural and synthetic rock systems. J Petrol 3:342–532
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Duncan, R.A., Green, D.H. The genesis of refractory melts in the formation of oceanic crust. Contr. Mineral. and Petrol. 96, 326–342 (1987). https://doi.org/10.1007/BF00371252
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DOI: https://doi.org/10.1007/BF00371252