Volatiles and trace elements content in melt inclusions from the zoned Green Tuff ignimbrite (Pantelleria, Sicily): petrological inferences
Author(s)
Language
English
Obiettivo Specifico
2V. Struttura e sistema di alimentazione dei vulcani
Status
Published
JCR Journal
JCR Journal
Peer review journal
Yes
Journal
Issue/vol(year)
/61 (2019)
ISSN
1593-5213
Electronic ISSN
2037-416X
Publisher
IStituto Nazionale di Geofisica e Vulcanologia
Pages (printed)
VO09
Date Issued
July 22, 2019
Subjects
Subjects
Abstract
The island of Pantelleria is one of the best known localities of bimodal mafic-felsic magmatism (alkali basalt and trachyte-pantellerite). Among the felsic rocks, the coexistence in a single eruption of products of both trachyte and pantellerite compositions is limited to few occurrences, the Green Tuff (GT) ignimbrite being one of these. The GT is compositionally zoned from pantellerite (70.1 wt% SiO2, mol Na+K/Al = 1.86, 1871 ppm Zr) at the base to crystal-rich (>30 vol%) comenditic trachyte (63.4 wt% SiO2, mol Na+K/Al = 1.10, 265 ppm Zr) at the top, although the pantellertic compositions dominate the erupted volume. We present here new data on melt inclusions (MIs) from the pantellerite portions of the GT eruption and, most importantly, from the trachyte member, which have not been studied in-situ by previous work focused on the GT. We document the first occurrence of trachytic melt inclusions in the late-erupted member, whose importance resides in the fact that trachytes were known mostly as crystal-rich lavas or ignimbrites, all variably affected by crystal accumulation. Besides the obvious inferences on the interplay between parental-derivative magmas, this evidence adds also some helpful elements in understanding zoning of silicic and peralkaline (i.e. low-viscosity) magma chambers. Trace elements compositions of MIs reveal that trachyte melts are of two types: (i) a low-Ba, directly descending from basaltic melts by 60-70 % of fractional crystallisation, and (ii) a high-Ba that might be affected by processes of feldspar dissolution and entrainment of the resulting small-scale melts in some MIs. MIs hosted in the deep-seated trachyte body are H2O-poor (≤ 1.2 wt %) with respect to the early erupted (and shallower) pantellerite magma (≤ 4.2 wt %), raising the possibility that either trachyte magma was H2O-undesaturated, or clinopyroxene hosted melt inclusions which suffered consistent H2O loss.
References
Andersen, D.J., D.H. Lindsley, and P.M. Davidson (1993). QUILF: a PASCAL program to assess equilibria among Fe–Mg–Mn–Ti oxides, pyroxenes, olivine, and quartz, Comp. and Geosc., 19, 1333–1350.
Bacon, C.R. and M.M. Hirschmann (1988). Mg/Mn partitioning as a test for equilibrium between coexisting Fe–Ti oxides, Am. Mineral., 73, 57-61.
Calanchi, N., P. Colantoni, P.L. Rossi, M. Saitta and G. Serri (1989). The Strait of Sicily continental rift systems: physiography and petrochemistry of the submarine volcanic centres, Mar. Geol., 57, 55-83.
Catalano, S., G. De Guidi, G. Romagnoli, S. Torrisi and L. Tortorici (2008). The migration of plate boundaries in the SE Sicily: influence of the large-scale kinematic model of African promontory in southern Italy, Tectonophysics, 449, 41-63.
Civetta, L., M. D’Antonio, G. Orsi and G.R. Tilton (1998). The geochemistry of volcanic rocks from Pantelleria island, Sicily channel:petrogenesis and characteristics of the mantle source region, J. Petrol., 39, 1453-1491.
Civile, D., E. Lodolo, L. Tortorici, G. Lanzafame and G. Brancolini (2008). - Relationships between magmatism and tectonics in a continental rift: The Pantelleria Island region (Sicily Channel, Italy), Mar. Geol., 251, 32-46.
Di Carlo, I., S.G. Rotolo, B. Scaillet, V. Buccheri and M. Pichavant (2010). Phase equilibrium constraints on pre-eruptive conditions of recent felsic explosive volcanism at Pantelleria Island, Italy, J. Petrol., 51, 2245-2276.
Dixon, J.E., E.M. Stolper,. and J.R. Holloway (1995). An experimental study of water and carbon dioxide solubilities in mid-ocean ridge basaltic liquids. Part I: calibration and solubility models, J. Petrol., 36, 1607–1631.
D’Oriano, C., P.Landi, A. Pimental and V. Zanon (2017). Magmatic processes revealed by anorthoclase textures and trace element modeling: The case of the Lajes Ignimbrite eruption (Terceira Island, Azores), J. Volcanol. Geoth. Res., 347, 44-63.
Edmonds, M. and P. J. Wallace (2017). Volatiles in volcanic systems. Elements 13, 29-33.
Ferla, P. and C. Meli (2006). Evidence of magma mixing in the “Daly Gap” of alkali suites: a case study from the enclaves of Pantelleria (Italy), J. Petrol., 47, 1467-1507.
Frost, B.R., D.H. Lindsley and D.J. Andersen (1988). Fe–Ti oxide–silicate equilibria: assemblages with fayalitic olivine, Am. Mineral., 73, 727–740.
Gioncada, A. and P. Landi (2010). The pre-eruptive volatile contents of recent basaltic and pantelleritic magmas at Pantelleria (Italy), J. Volcanol. Geoth. Res., 189, 191-201.
Gualda, G. A. R., M.S. Ghiorso, R.V Lemons and T.L. Carley (2012). Rhyolite-MELTS: a modified calibration of MELTS optimized for silica-rich, fluidbearing magmatic systems, J. Petrol, 53, 875–890.
Hildreth, W. (1981). Gradients in silicic magma chambers: Implications for lithospheric magmatism, J. Geophys. Res., 86, 10153-10192.
Jordan, N.J., S.G. Rotolo, R. Williams, F. Speranza, WC. McIntosh, M.J, Branney and S. Scaillet (2018). Explosive eruptive history of Pantelleria, Italy: repeated caldera collapse and ignimbrite formation at a peralkaline volcano, J. Volcanol. Geoth. Res., 349, 67-73.
Kennedy, G.C. (1955). Some aspects of the role of water in rock melts, Geol. Soc. Am. Sp. Pap., 62, 489-504.
Lanzo, G., P. Landi, and S.G. Rotolo (2013). Volatiles in pantellerite magmas: a case study of the Green Tuff Plinian eruption, J. Volcanol. Geoth. Res., 262, 153-163.
Lowenstern, J.B., 1994. Chlorine, fluid immiscibility, and degassing in peralkaline magmasfrom Pantelleria, Italy, Am. Mineral., 79, 353–369.
Lowenstern, J.B. and G.A. Mahood (1991). New data on magmatic H2O contents with implications for petrogenesis and eruptive dynamics at Pantelleria, Bull. Volcanol., 54, 78-83.
McDonough, W.F. and S. Sun (1995). Composition of the Earth, Chem Geol., 120, 223-253.
Mahood, G.A. and W. Hildreth (1986). Geology of the peralkaline volcano at Pantelleria, Strait of Sicily, Bull. Volcanol., 48, 143-172.
Mahood, G.A. and J.A Stimac (1990). Trace-element partitioning in pantellerites and trachytes,
17
A MELT INCLUSION STUDY OF THE ZONED GREEN TUFF IGNIMBRITE (PANTELLERIA, SICILY)
Geochim. Cosmochim. Acta., 54, 2257-2276.
Métrich, N., J. Susini, E. Foy, F. Farges, D. Massare, L. Sylla, S. Lequien and M. Bonin-Mossba (2006). Redox state of iron in peralkaline rhyolitic glass/melt X-ray absorption micro-spectroscopy experiments at high temperature, Chem. Geol. 231, 350-363.
Neave, D.A., G. Fabbro, R.A. Herd, C.M Petrone. and M. Edmonds (2012). Melting, differentiation and degassing at the Pantelleria volcano, Italy, J. Petrol., 53 637-663.
Romano, P. (2017). Experimental investigation on peralkaline silicic magmas of Pantelleria Island: inferences on pre-eruptive conditions, magma evolution and water solubility, PhD thesis, University of Palermo.
Romano, P., J. Andújar, B. Scaillet, N. Romengo, I. Di Carlo and S.G. Rotolo (2018). Phase equilibria of Pantelleria trachytes (Italy): Constraints on pre-eruptive conditions and on the metaluminous to peralkaline transition in silicic magmas. J. Petrol., in press, doi: 10.1093/petrology/egy037.
Rotolo, S.G., F. Castorina, D. Cellura and M. Pompilio (2006). Petrology and Geochemistry of submarine volcanism in the Sicily Channel Rift, J. Geol., 114/3 355-365.
Scaillet, B. and R. Macdonald (2001). Phase relations of peralkaline silicic magmas and petrogenetic implications, J. Petrol., 42, 825-845.
Scaillet, B. and R. Macdonald (2003). Experimental constraints on the relationships between peralkaline rhyolites of the Kenya rift valley, J. Petrol., 44, 1867-1894.
Scaillet, B. and R. Macdonald (2006). Experimental and thermodynamic constraints on the sulphur yield of peralkaline and Metaluminous silicic flood eruptions, J. Petrol., 47, 1413-1437.
Scaillet, S., G. Vita-Scaillet and S. G. Rotolo (2013). Millenial-scale phase relationships between ice-core and Mediterranean marine records: insights from high-precision 40Ar/39Ar dating of the Green Tuff of Pantelleria, Sicily Strait. Quat. Sci. Rev., 78, 141-154.
Tait, S., C. Jaupart and S. Vergniolle (1989). Pressure, gas content and eruption periodicity of a shallow, crystallizing magma chamber, Earth Planet. Sci. Lett., 92(1), 107–123.
White, J.C., D.F. Parker and M. Ren (2009). The origin of trachyte and pantellerite from Pantelleria, Italy: insights from major elements, trace elements, and thermodynamic modelling, J. Volcanol. Geoth. Res., 179, 33-55.
Williams, R., (2010). Emplacement of Radial Pyroclastic Density Currents Over Irregular Topography: The Chemically-zoned, Low Aspect-ratio Green Tuff Ignimbrite, Pantelleria, Italy, University of Leicester, https://doi.org/10.6084/m9.figshare.789054.v1 PhD thesis.
Williams, R., M.J. Branney and T.L. Barry (2014). Temporal and spatial evolution of a waxing then waning catastrophic density current revealed by chemical mapping. Geology, 42, 107–110.
Wolff, J.A., G. Görner and S. Blake (1990). Gradients in physical parameters in zoned felsic bodies: implications for evolution and eruptive withdrawal, J. Volcanol. Geoth. Res., 43, 37-55.
Bacon, C.R. and M.M. Hirschmann (1988). Mg/Mn partitioning as a test for equilibrium between coexisting Fe–Ti oxides, Am. Mineral., 73, 57-61.
Calanchi, N., P. Colantoni, P.L. Rossi, M. Saitta and G. Serri (1989). The Strait of Sicily continental rift systems: physiography and petrochemistry of the submarine volcanic centres, Mar. Geol., 57, 55-83.
Catalano, S., G. De Guidi, G. Romagnoli, S. Torrisi and L. Tortorici (2008). The migration of plate boundaries in the SE Sicily: influence of the large-scale kinematic model of African promontory in southern Italy, Tectonophysics, 449, 41-63.
Civetta, L., M. D’Antonio, G. Orsi and G.R. Tilton (1998). The geochemistry of volcanic rocks from Pantelleria island, Sicily channel:petrogenesis and characteristics of the mantle source region, J. Petrol., 39, 1453-1491.
Civile, D., E. Lodolo, L. Tortorici, G. Lanzafame and G. Brancolini (2008). - Relationships between magmatism and tectonics in a continental rift: The Pantelleria Island region (Sicily Channel, Italy), Mar. Geol., 251, 32-46.
Di Carlo, I., S.G. Rotolo, B. Scaillet, V. Buccheri and M. Pichavant (2010). Phase equilibrium constraints on pre-eruptive conditions of recent felsic explosive volcanism at Pantelleria Island, Italy, J. Petrol., 51, 2245-2276.
Dixon, J.E., E.M. Stolper,. and J.R. Holloway (1995). An experimental study of water and carbon dioxide solubilities in mid-ocean ridge basaltic liquids. Part I: calibration and solubility models, J. Petrol., 36, 1607–1631.
D’Oriano, C., P.Landi, A. Pimental and V. Zanon (2017). Magmatic processes revealed by anorthoclase textures and trace element modeling: The case of the Lajes Ignimbrite eruption (Terceira Island, Azores), J. Volcanol. Geoth. Res., 347, 44-63.
Edmonds, M. and P. J. Wallace (2017). Volatiles in volcanic systems. Elements 13, 29-33.
Ferla, P. and C. Meli (2006). Evidence of magma mixing in the “Daly Gap” of alkali suites: a case study from the enclaves of Pantelleria (Italy), J. Petrol., 47, 1467-1507.
Frost, B.R., D.H. Lindsley and D.J. Andersen (1988). Fe–Ti oxide–silicate equilibria: assemblages with fayalitic olivine, Am. Mineral., 73, 727–740.
Gioncada, A. and P. Landi (2010). The pre-eruptive volatile contents of recent basaltic and pantelleritic magmas at Pantelleria (Italy), J. Volcanol. Geoth. Res., 189, 191-201.
Gualda, G. A. R., M.S. Ghiorso, R.V Lemons and T.L. Carley (2012). Rhyolite-MELTS: a modified calibration of MELTS optimized for silica-rich, fluidbearing magmatic systems, J. Petrol, 53, 875–890.
Hildreth, W. (1981). Gradients in silicic magma chambers: Implications for lithospheric magmatism, J. Geophys. Res., 86, 10153-10192.
Jordan, N.J., S.G. Rotolo, R. Williams, F. Speranza, WC. McIntosh, M.J, Branney and S. Scaillet (2018). Explosive eruptive history of Pantelleria, Italy: repeated caldera collapse and ignimbrite formation at a peralkaline volcano, J. Volcanol. Geoth. Res., 349, 67-73.
Kennedy, G.C. (1955). Some aspects of the role of water in rock melts, Geol. Soc. Am. Sp. Pap., 62, 489-504.
Lanzo, G., P. Landi, and S.G. Rotolo (2013). Volatiles in pantellerite magmas: a case study of the Green Tuff Plinian eruption, J. Volcanol. Geoth. Res., 262, 153-163.
Lowenstern, J.B., 1994. Chlorine, fluid immiscibility, and degassing in peralkaline magmasfrom Pantelleria, Italy, Am. Mineral., 79, 353–369.
Lowenstern, J.B. and G.A. Mahood (1991). New data on magmatic H2O contents with implications for petrogenesis and eruptive dynamics at Pantelleria, Bull. Volcanol., 54, 78-83.
McDonough, W.F. and S. Sun (1995). Composition of the Earth, Chem Geol., 120, 223-253.
Mahood, G.A. and W. Hildreth (1986). Geology of the peralkaline volcano at Pantelleria, Strait of Sicily, Bull. Volcanol., 48, 143-172.
Mahood, G.A. and J.A Stimac (1990). Trace-element partitioning in pantellerites and trachytes,
17
A MELT INCLUSION STUDY OF THE ZONED GREEN TUFF IGNIMBRITE (PANTELLERIA, SICILY)
Geochim. Cosmochim. Acta., 54, 2257-2276.
Métrich, N., J. Susini, E. Foy, F. Farges, D. Massare, L. Sylla, S. Lequien and M. Bonin-Mossba (2006). Redox state of iron in peralkaline rhyolitic glass/melt X-ray absorption micro-spectroscopy experiments at high temperature, Chem. Geol. 231, 350-363.
Neave, D.A., G. Fabbro, R.A. Herd, C.M Petrone. and M. Edmonds (2012). Melting, differentiation and degassing at the Pantelleria volcano, Italy, J. Petrol., 53 637-663.
Romano, P. (2017). Experimental investigation on peralkaline silicic magmas of Pantelleria Island: inferences on pre-eruptive conditions, magma evolution and water solubility, PhD thesis, University of Palermo.
Romano, P., J. Andújar, B. Scaillet, N. Romengo, I. Di Carlo and S.G. Rotolo (2018). Phase equilibria of Pantelleria trachytes (Italy): Constraints on pre-eruptive conditions and on the metaluminous to peralkaline transition in silicic magmas. J. Petrol., in press, doi: 10.1093/petrology/egy037.
Rotolo, S.G., F. Castorina, D. Cellura and M. Pompilio (2006). Petrology and Geochemistry of submarine volcanism in the Sicily Channel Rift, J. Geol., 114/3 355-365.
Scaillet, B. and R. Macdonald (2001). Phase relations of peralkaline silicic magmas and petrogenetic implications, J. Petrol., 42, 825-845.
Scaillet, B. and R. Macdonald (2003). Experimental constraints on the relationships between peralkaline rhyolites of the Kenya rift valley, J. Petrol., 44, 1867-1894.
Scaillet, B. and R. Macdonald (2006). Experimental and thermodynamic constraints on the sulphur yield of peralkaline and Metaluminous silicic flood eruptions, J. Petrol., 47, 1413-1437.
Scaillet, S., G. Vita-Scaillet and S. G. Rotolo (2013). Millenial-scale phase relationships between ice-core and Mediterranean marine records: insights from high-precision 40Ar/39Ar dating of the Green Tuff of Pantelleria, Sicily Strait. Quat. Sci. Rev., 78, 141-154.
Tait, S., C. Jaupart and S. Vergniolle (1989). Pressure, gas content and eruption periodicity of a shallow, crystallizing magma chamber, Earth Planet. Sci. Lett., 92(1), 107–123.
White, J.C., D.F. Parker and M. Ren (2009). The origin of trachyte and pantellerite from Pantelleria, Italy: insights from major elements, trace elements, and thermodynamic modelling, J. Volcanol. Geoth. Res., 179, 33-55.
Williams, R., (2010). Emplacement of Radial Pyroclastic Density Currents Over Irregular Topography: The Chemically-zoned, Low Aspect-ratio Green Tuff Ignimbrite, Pantelleria, Italy, University of Leicester, https://doi.org/10.6084/m9.figshare.789054.v1 PhD thesis.
Williams, R., M.J. Branney and T.L. Barry (2014). Temporal and spatial evolution of a waxing then waning catastrophic density current revealed by chemical mapping. Geology, 42, 107–110.
Wolff, J.A., G. Görner and S. Blake (1990). Gradients in physical parameters in zoned felsic bodies: implications for evolution and eruptive withdrawal, J. Volcanol. Geoth. Res., 43, 37-55.
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