Role of non-mantle CO2 in the dynamics of volcano degassing: The Mount Vesuvius example
Author(s)
Language
English
Obiettivo Specifico
4.5. Studi sul degassamento naturale e sui gas petroliferi
Status
Published
JCR Journal
JCR Journal
Peer review journal
Yes
Journal
Issue/vol(year)
4/37 (2009)
Publisher
GSA
Pages (printed)
319-322
Date Issued
April 2009
Abstract
Mount Vesuvius, Italy, quiescent since A.D. 1944, is a dangerous volcano currently characterized by elevated CO2 emissions of debated origin. We show that such emissions are most likely the surface manifestation of the deep intrusion of alkalic-basaltic magma into the sedimentary carbonate basement, accompanied by sidewall assimilation and CO2 volatilization. During the last eruptive period (1631–1944), the carbonate-sourced CO2 made up 4.7–5.3 wt%
of the vented magma. On a yearly basis, the resulting CO2 production rate is comparable to CO2 emissions currently measured in the volcanic area. The chemical and isotopic composition of the fumaroles supports the predominance of this crust-derived CO2 in volatile emissions at Mount Vesuvius.
of the vented magma. On a yearly basis, the resulting CO2 production rate is comparable to CO2 emissions currently measured in the volcanic area. The chemical and isotopic composition of the fumaroles supports the predominance of this crust-derived CO2 in volatile emissions at Mount Vesuvius.
References
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Berrino, G., Corrado, G., and Riccardi, U., 1998, Sea gravity data in the Gulf of
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Blank, J.G., and Brooker, R.A., 1994, Experimental studies of carbon dioxide in
silicate melts: Solubility, speciation, and stable carbon isotope behavior, in
Carroll, M.R., and Holloway J.R., eds., Volatiles in magmas: Mineralogical
Society of America Reviews in Mineralogy, v. 30, p. 157–186.
Bottinga, Y., and Richet, P., 1981, High pressure and temperature equation of
state and calculation of the thermodynamic properties of gaseous carbon
dioxide: American Journal of Science, v. 281, p. 615–660.
Brocchini, D., Principe, C., Castradori, D., Laurenzi, M.A., and Gorla, L., 2001,
Quaternary evolution of the southern sector of the Campanian Plain and
early Somma-Vesuvius activity: Insights from the Trecase 1 well: Mineralogy
and Petrology, v. 73, p. 67–91, doi: 10.1007/s007100170011.
Caliro, S., Chiodini, G., Avino, R., Cardellini, C., and Frondini, F., 2005, Vol canic
degassing at Somma–Vesuvio (Italy) inferred by chemical and isotopic signatures
of groundwater: Applied Geochemistry, v. 20, p. 1060–1076, doi:
10.1016/j.apgeochem.2005.02.002.
Chadwick, J.P., Troll, V.R., Ginibre, C., Morgan, D., Gertisser, R., Waight, T.E.,
and Davidson, J.P., 2007, Carbonate assimilation at Merapi Volcano, Java,
Indonesia: Insights from crystal isotope stratigraphy: Journal of Petrology,
v. 48, p. 1793–1812, doi: 10.1093/petrology/egm038.
Chiodini, G., Marini, L., and Russo, M., 2001, Geochemical evidence for the
exis tence of high-temperature hydrothermal brines at Vesuvio volcano,
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10.1016/S0016–7037(01)00583-X.
Civetta, L., and Santacroce, R., 1992, Steady state magma supply in the last 3400
years of Vesuvius activity: Acta Vulcanologica, v. 2, p. 147–159.
D’Argenio, B., and Alvarez, W., 1980, Stratigraphic evidence for crustal thickness
changes on the Southern Tethyan margin during the Alpine cycle: Geological
Society of America Bulletin, v. 91, p. 681–689, doi: 10.1130/0016–
7606(1980)91<681:SEFCTC>2.0.CO;2.
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p. 642–651, doi: 10.1007/s00445–004–0346-x.
Fulignati, P., Marianelli, P., Métrich, N., Santacroce, R., and Sbrana, A., 2004,
Towards a reconstruction of the magmatic feeding system of the 1944 eruption
of Mt Vesuvius: Journal of Volcanology and Geothermal Research,
v. 133, p. 13–22, doi: 10.1016/S0377–0273(03)00388–3.
Gilg, H.A., Lima, A., Somma, R., Ayuso, R.A., Belkin, H.E., and De Vivo,
B., 2001, Isotope geochemistry and fl uid inclusion study of skarns from
Vesuvius: Mineralogy and Petrology, v. 73, p. 145–176, doi: 10.1007/
s007100170015.
Goff, F., Love, S.P., Warren, R.G., Counce, D., Obenholzner, J., Siebe, C., and
Schmidt, S.C., 2001, Passive infrared remote sensing evidence for large,
inter mittent CO2 emissions at Popocatepetl volcano, Mexico: Chemical
Geol ogy, v. 177, p. 133–156, doi: 10.1016/S0009–2541(00)00387–9.
Iacono-Marziano, G., Gaillard, F., and Pichavant, M., 2007, Limestone
assimi lation and the origin of CO2 emissions at the Alban Hills (Central
Italy): Constraints from experimental petrology: Journal of Volcanology
and Geothermal Research, v. 166, p. 91–105, doi: 10.1016/
j.jvolgeores.2007.07.001.
Iacono-Marziano, G., Gaillard, F., and Pichavant, M., 2008, Limestone assimilation
by basaltic magmas: An experimental re-assessment and application
to Italian volcanoes: Contributions to Mineralogy and Petrology, v. 155,
p. 719–738, doi: 10.1007/s00410–007–0267–8.
Joron, J.L., Metrich, N., Rosi, M., Santacroce, R., and Sbrana, A., 1987, Chemistry
and petrography, in Santacroce, R., ed., Somma-Vesuvius: Quaderni de
la ricerca scientifi ca, CNR, Roma, v. 8, p. 105–171.
Marianelli, P., Sbrana, A., Metrich, N., and Cecchetti, A., 2005, The deep feeding
system of Vesuvius involved in recent violent strombolian eruptions: Geophysical
Research Letters, v. 32, L02306, doi: 10.1029/2004GL021667.
Martelli, M., Nuccio, P.M., Stuart, F.M., Burgess, R., Ellam, R.M., and Italiano,
F., 2004, Helium-strontium isotope constraints on mantle evolution beneath
the Roman comagmatic province, Italy: Earth and Planetary Science Letters,
v. 224, p. 295–308, doi: 10.1016/j.epsl.2004.05.025.
Michaud, V., 1995, Crustal xenoliths in recent hawaiites from Mount Etna, Italy:
Evidence for alkali exchanges during magma-wall rock interaction: Chemical
Geology, v. 122, p. 21–42, doi: 10.1016/0009–2541(94)00133-S.
Obenholzner, J.H., Schroettner, H., Golob, P., and Delgado, H., 2003, Particles
from the plume of Popocatépetl volcano, Mexico—The FESEM/EDS approach,
in Oppenheimer, C., et al., eds., Volcanic degassing: Geological
Society of London Special Publication 213, p. 123–148.
Parello, F., Allard, P., D’Alessandro, W., Federico, C., Jean-Baptiste, P., and
Catani , O., 2000, Isotope geochemistry of Pantelleria volcanic fl uids,
Sicily Channel rift: A mantle volatile end-member for volcanism in southern
Europe : Earth and Planetary Science Letters, v. 180, p. 325–339, doi:
10.1016/S0012–821X(00)00183–7.
Parente, M., Frijia, G., and Di Lucia, M., 2007, Carbon-isotope stratigraphy of
Cenomanian-Turonian platform carbonates from the southern Apennines
(Italy): A chemostratigraphic approach to the problem of correlation between
shallow-water and deep-water successions: Geological Society of
London Journal, v. 164, p. 609–620.
Pineau, F., Shilobreeva, S., Hekinian, R., Bideau, D., and Javoy, M., 2004, Deepsea
explosive activity on the Mid-Atlantic Ridge near 34°50′N: A stable isotope
(C, H, O) study: Chemical Geology, v. 211, p. 159–175, doi: 10.1016/
j.chemgeo.2004.06.029.
Rittmann, A., 1933, Evolution and differentiation des Somma-Vesuv-magmas:
Zeitschrift für Vulkanologie, v. 15, p. 8–94.
Rosi, M., Santacroce, R., and Sheridan, M.F., 1987, Volcanic hazard, in
Santacroce , R., ed., Somma-Vesuvius: Quaderni de la ricerca scientifi ca,
CNR, Roma, v. 8, p. 197–220.
Sano, Y., and Marty, B., 1995, Origin of carbon in fumarolic gas from island
arcs: Chemical Geology, v. 119, p. 265–274, doi: 10.1016/0009–2541(94)
00097-R.
Scaillet, B., Pichavant, M., and Cioni, R., 2008, Upward migration of Vesuvius
magma chamber over the past 20 thousand years: Nature, v. 455, p. 216–
219, doi: 10.1038/nature07232.
Scandone, R., Giacomelli, L., and Fattori Speranza, F., 2008, Persistent activity
and violent strombolian eruptions at Vesuvius between 1631 and 1944:
Journal of Volcanology and Geothermal Research, v. 170, p. 167–180, doi:
10.1016/j.jvolgeores.2007.09.014.
Tedesco, D., Nagao, K., and Scarsi, P., 1998, Noble gas isotopic ratios from historical
lavas and fumaroles at Mount Vesuvius (southern Italy): Constraints
for current and future volcanic activity: Earth and Planetary Science Letters,
v. 164, p. 61–78, doi: 10.1016/S0012–821X(98)00167–8.
Werner, C., and Brantley, S., 2003, CO2 emissions from the Yellowstone volcanic
system: Geochemistry, Geophysics, Geosystems, v. 4, 1061, doi:
10.1029/2002GC000473.
extended magmatic sill under Mt. Vesuvius: Science, v. 294, p. 1510–1512,
doi: 10.1126/science.1064893.
Barnes, C.G., Prestvik, T., Sundvoll, B., and Surratt, D., 2005, Pervasive assimilation
of carbonate and silicate rocks in the Hortavær igneous complex,
north-central Norway: Lithos, v. 80, p. 179–199, doi: 10.1016/j.lithos.
2003.11.002.
Behrens, H., and Gaillard, F., 2006, Geochemical aspects of melts: Volatiles and
redox behaviour: Elements, v. 2, p. 275–280, doi: 10.2113/gselements.
2.5.275.
Berrino, G., Corrado, G., and Riccardi, U., 1998, Sea gravity data in the Gulf of
Naples: A contribution to delineating the structural pattern of the Vesuvian
area: Journal of Volcanology and Geothermal Research, v. 82, p. 139–150.
Blank, J.G., and Brooker, R.A., 1994, Experimental studies of carbon dioxide in
silicate melts: Solubility, speciation, and stable carbon isotope behavior, in
Carroll, M.R., and Holloway J.R., eds., Volatiles in magmas: Mineralogical
Society of America Reviews in Mineralogy, v. 30, p. 157–186.
Bottinga, Y., and Richet, P., 1981, High pressure and temperature equation of
state and calculation of the thermodynamic properties of gaseous carbon
dioxide: American Journal of Science, v. 281, p. 615–660.
Brocchini, D., Principe, C., Castradori, D., Laurenzi, M.A., and Gorla, L., 2001,
Quaternary evolution of the southern sector of the Campanian Plain and
early Somma-Vesuvius activity: Insights from the Trecase 1 well: Mineralogy
and Petrology, v. 73, p. 67–91, doi: 10.1007/s007100170011.
Caliro, S., Chiodini, G., Avino, R., Cardellini, C., and Frondini, F., 2005, Vol canic
degassing at Somma–Vesuvio (Italy) inferred by chemical and isotopic signatures
of groundwater: Applied Geochemistry, v. 20, p. 1060–1076, doi:
10.1016/j.apgeochem.2005.02.002.
Chadwick, J.P., Troll, V.R., Ginibre, C., Morgan, D., Gertisser, R., Waight, T.E.,
and Davidson, J.P., 2007, Carbonate assimilation at Merapi Volcano, Java,
Indonesia: Insights from crystal isotope stratigraphy: Journal of Petrology,
v. 48, p. 1793–1812, doi: 10.1093/petrology/egm038.
Chiodini, G., Marini, L., and Russo, M., 2001, Geochemical evidence for the
exis tence of high-temperature hydrothermal brines at Vesuvio volcano,
Italy : Geochimica et Cosmochimica Acta, v. 65, p. 2129–2147, doi:
10.1016/S0016–7037(01)00583-X.
Civetta, L., and Santacroce, R., 1992, Steady state magma supply in the last 3400
years of Vesuvius activity: Acta Vulcanologica, v. 2, p. 147–159.
D’Argenio, B., and Alvarez, W., 1980, Stratigraphic evidence for crustal thickness
changes on the Southern Tethyan margin during the Alpine cycle: Geological
Society of America Bulletin, v. 91, p. 681–689, doi: 10.1130/0016–
7606(1980)91<681:SEFCTC>2.0.CO;2.
De Natale, G., Troise, C., Pingue, F., Mastrolorenzo, G., and Pappalardo, L.,
2006, The Somma–Vesuvius volcano (Southern Italy): Structure, dynamics
and hazard evaluation: Earth-Science Reviews, v. 74, p. 73–111, doi:
10.1016/j.earscirev.2005.08.001.
Di Renzo, V., Di Vito, M.A., Arienzo, I., Carandente, A., Civetta, L., D’antonio,
M., Giordano, F., Orsi, G., and Tonarini, S., 2007, Magmatic history of
Somma-Vesuvius on the basis of new geochemical and isotopic data
from a deep borehole (Camaldoli della Torre): Journal of Petrology, v. 48,
p. 753–784, doi: 10.1093/petrology/egl081.
Federico, C., Aiuppa, A., Allard, P., Bellomo, S., Jean-Baptiste, P., Parello, F., and
Valenza, M., 2002, Magma-derived gas infl ux and water-rock interactions
in the volcanic aquifer of Mt. Vesuvius, Italy: Geochimica et Cosmochimica
Acta, v. 66, p. 963–981, doi: 10.1016/S0016–7037(01)00813–4.
Frondini, F., Chiodini, G., Caliro, S., Cardellini, C., and Granieri, D., 2004, Diffuse
CO2 soil degassing at Vesuvio, Italy: Bulletin of Volcanology, v. 66,
p. 642–651, doi: 10.1007/s00445–004–0346-x.
Fulignati, P., Marianelli, P., Métrich, N., Santacroce, R., and Sbrana, A., 2004,
Towards a reconstruction of the magmatic feeding system of the 1944 eruption
of Mt Vesuvius: Journal of Volcanology and Geothermal Research,
v. 133, p. 13–22, doi: 10.1016/S0377–0273(03)00388–3.
Gilg, H.A., Lima, A., Somma, R., Ayuso, R.A., Belkin, H.E., and De Vivo,
B., 2001, Isotope geochemistry and fl uid inclusion study of skarns from
Vesuvius: Mineralogy and Petrology, v. 73, p. 145–176, doi: 10.1007/
s007100170015.
Goff, F., Love, S.P., Warren, R.G., Counce, D., Obenholzner, J., Siebe, C., and
Schmidt, S.C., 2001, Passive infrared remote sensing evidence for large,
inter mittent CO2 emissions at Popocatepetl volcano, Mexico: Chemical
Geol ogy, v. 177, p. 133–156, doi: 10.1016/S0009–2541(00)00387–9.
Iacono-Marziano, G., Gaillard, F., and Pichavant, M., 2007, Limestone
assimi lation and the origin of CO2 emissions at the Alban Hills (Central
Italy): Constraints from experimental petrology: Journal of Volcanology
and Geothermal Research, v. 166, p. 91–105, doi: 10.1016/
j.jvolgeores.2007.07.001.
Iacono-Marziano, G., Gaillard, F., and Pichavant, M., 2008, Limestone assimilation
by basaltic magmas: An experimental re-assessment and application
to Italian volcanoes: Contributions to Mineralogy and Petrology, v. 155,
p. 719–738, doi: 10.1007/s00410–007–0267–8.
Joron, J.L., Metrich, N., Rosi, M., Santacroce, R., and Sbrana, A., 1987, Chemistry
and petrography, in Santacroce, R., ed., Somma-Vesuvius: Quaderni de
la ricerca scientifi ca, CNR, Roma, v. 8, p. 105–171.
Marianelli, P., Sbrana, A., Metrich, N., and Cecchetti, A., 2005, The deep feeding
system of Vesuvius involved in recent violent strombolian eruptions: Geophysical
Research Letters, v. 32, L02306, doi: 10.1029/2004GL021667.
Martelli, M., Nuccio, P.M., Stuart, F.M., Burgess, R., Ellam, R.M., and Italiano,
F., 2004, Helium-strontium isotope constraints on mantle evolution beneath
the Roman comagmatic province, Italy: Earth and Planetary Science Letters,
v. 224, p. 295–308, doi: 10.1016/j.epsl.2004.05.025.
Michaud, V., 1995, Crustal xenoliths in recent hawaiites from Mount Etna, Italy:
Evidence for alkali exchanges during magma-wall rock interaction: Chemical
Geology, v. 122, p. 21–42, doi: 10.1016/0009–2541(94)00133-S.
Obenholzner, J.H., Schroettner, H., Golob, P., and Delgado, H., 2003, Particles
from the plume of Popocatépetl volcano, Mexico—The FESEM/EDS approach,
in Oppenheimer, C., et al., eds., Volcanic degassing: Geological
Society of London Special Publication 213, p. 123–148.
Parello, F., Allard, P., D’Alessandro, W., Federico, C., Jean-Baptiste, P., and
Catani , O., 2000, Isotope geochemistry of Pantelleria volcanic fl uids,
Sicily Channel rift: A mantle volatile end-member for volcanism in southern
Europe : Earth and Planetary Science Letters, v. 180, p. 325–339, doi:
10.1016/S0012–821X(00)00183–7.
Parente, M., Frijia, G., and Di Lucia, M., 2007, Carbon-isotope stratigraphy of
Cenomanian-Turonian platform carbonates from the southern Apennines
(Italy): A chemostratigraphic approach to the problem of correlation between
shallow-water and deep-water successions: Geological Society of
London Journal, v. 164, p. 609–620.
Pineau, F., Shilobreeva, S., Hekinian, R., Bideau, D., and Javoy, M., 2004, Deepsea
explosive activity on the Mid-Atlantic Ridge near 34°50′N: A stable isotope
(C, H, O) study: Chemical Geology, v. 211, p. 159–175, doi: 10.1016/
j.chemgeo.2004.06.029.
Rittmann, A., 1933, Evolution and differentiation des Somma-Vesuv-magmas:
Zeitschrift für Vulkanologie, v. 15, p. 8–94.
Rosi, M., Santacroce, R., and Sheridan, M.F., 1987, Volcanic hazard, in
Santacroce , R., ed., Somma-Vesuvius: Quaderni de la ricerca scientifi ca,
CNR, Roma, v. 8, p. 197–220.
Sano, Y., and Marty, B., 1995, Origin of carbon in fumarolic gas from island
arcs: Chemical Geology, v. 119, p. 265–274, doi: 10.1016/0009–2541(94)
00097-R.
Scaillet, B., Pichavant, M., and Cioni, R., 2008, Upward migration of Vesuvius
magma chamber over the past 20 thousand years: Nature, v. 455, p. 216–
219, doi: 10.1038/nature07232.
Scandone, R., Giacomelli, L., and Fattori Speranza, F., 2008, Persistent activity
and violent strombolian eruptions at Vesuvius between 1631 and 1944:
Journal of Volcanology and Geothermal Research, v. 170, p. 167–180, doi:
10.1016/j.jvolgeores.2007.09.014.
Tedesco, D., Nagao, K., and Scarsi, P., 1998, Noble gas isotopic ratios from historical
lavas and fumaroles at Mount Vesuvius (southern Italy): Constraints
for current and future volcanic activity: Earth and Planetary Science Letters,
v. 164, p. 61–78, doi: 10.1016/S0012–821X(98)00167–8.
Werner, C., and Brantley, S., 2003, CO2 emissions from the Yellowstone volcanic
system: Geochemistry, Geophysics, Geosystems, v. 4, 1061, doi:
10.1029/2002GC000473.
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