Shallow seep-related seafloor features along the Malta plateau (Sicily channel – Mediterranean Sea): Morphologies and geo-environmental control of their distribution
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)
9/26 (2009)
Publisher
Elsevier Ltd.
Pages (printed)
1831-1848
Date Issued
November 2009
Abstract
Between 140 and 170 m water depth, more than 100 small-scale domes and peculiar ridges were mapped a few miles offshore of south-eastern Sicily along the Malta plateau (eastern Mediterranean Sea), Swath
bathymetric data along with a dense grid of side scan sonar and seismic profiles were acquired in an area extending over 100 km2. Gravity cores, water samples and video observations were also collected at
selected sites. Mapped domes were found from 50 to 200 m wide and no more than 5 m high occurring on the seafloor, isolated or arranged in clusters. Ridges consisted of large tabular sub-elongated structures,
elevated from 5 to 10 m from the surrounding seafloor, and had flat tops on which numerous closeset, small cones occurred, appearing in video observation as carbonate buildings strongly colonized by gorgonians. Characteristic acoustic signatures (i.e. blank areas and/or turbidity zones and enhanced reflections in seismic records), measured gas anomalies in seawater samples and detected plumes on echosounder profiles suggest that both the domes and ridges are influenced by active seeps. In addition,
their spatial distribution reflected patterns of tectonic lineaments produced by the late Miocene to present-day geo-dynamic evolution of the Malta plateau, which is also an important hydrocarbon province. Results from gravity cores suggest that mud extrusion seems to be the main process responsible for the origin of the domes, which are formed by gray mud with only a few centimeters of biogenic sand at the top, indicating that recent bioclastic material is not a major contributor to mound building.
However, at present, active degassing appears to be the main process that controls the morphological and sedimentological expression of both the domes and ridges. Therefore, a quiescent or intermittent
active stage for mud extrusion is considered.
bathymetric data along with a dense grid of side scan sonar and seismic profiles were acquired in an area extending over 100 km2. Gravity cores, water samples and video observations were also collected at
selected sites. Mapped domes were found from 50 to 200 m wide and no more than 5 m high occurring on the seafloor, isolated or arranged in clusters. Ridges consisted of large tabular sub-elongated structures,
elevated from 5 to 10 m from the surrounding seafloor, and had flat tops on which numerous closeset, small cones occurred, appearing in video observation as carbonate buildings strongly colonized by gorgonians. Characteristic acoustic signatures (i.e. blank areas and/or turbidity zones and enhanced reflections in seismic records), measured gas anomalies in seawater samples and detected plumes on echosounder profiles suggest that both the domes and ridges are influenced by active seeps. In addition,
their spatial distribution reflected patterns of tectonic lineaments produced by the late Miocene to present-day geo-dynamic evolution of the Malta plateau, which is also an important hydrocarbon province. Results from gravity cores suggest that mud extrusion seems to be the main process responsible for the origin of the domes, which are formed by gray mud with only a few centimeters of biogenic sand at the top, indicating that recent bioclastic material is not a major contributor to mound building.
However, at present, active degassing appears to be the main process that controls the morphological and sedimentological expression of both the domes and ridges. Therefore, a quiescent or intermittent
active stage for mud extrusion is considered.
References
Barberi, F., Civetta, L., Gasparini, P., Innocenti, F., Scandone, R., Villari, L., 1974.
Evolution of a section of the Africa–Europe plate boundary; paleomagnetic and
volcanological evidence from Sicily. Earth Planetary Science Letters 22 (2),
123–132.
Brown, K.M., 1990. Nature and hydrogeologic significance of mud diapirs and
diatremes for accretionary systems. Journal of Geophysical Research 95,
8969–8982.
Butler, R.W.H., 1997. Depositional patterns and their tectonic controls within the
Plio-Quaternary carbonate sand and muds of onshore and offshore SE Sicily
(Italy). Marine and Petroleum Geology 14 (7/8), 879–892.
Camerlenghi, A., Pini, G.A., 2009. Mud volcanoes, olistostromes and Argille scagliose
in the Mediterranean region. Sedimentology 56, 319–365.
Cangemi, M., Bellanca, A., Neri, R., Scopelliti, G., 2008. Biomineralization events in
Recent volcanic and sedimentary settings: textural features and isotope
signatures. In: 33rd International Geology Congress, Oslo 2008.
Castradori, D., 1993. Calcareous nannofossil biostratigraphy and biochronology in
eastern Mediterranean deep-sea cores. Rivista Italiana di Paleontologia e
Stratigrafia 99 (1), 107–126.
Ceramicola, S., Praeg, D., Wardell, N., Unnithan, V., 2007. Seismic imaging of mud
volcanoes on the Calabrian Arc accretionary prism, central Mediterranean Sea.
Eos, Transactions, American Geophysical Union 88 (52) SUPPL., Abstract V22C-
05, Dec 2007.
Cita, M.B., Ivanov, M.K.,Woodside, J.M., 1996. The Mediterranean Ridge Diapiric Belt.
Marine Geology 132, 1–6.
Dimitrov, L.I., 2002. Mud volcanoes - the most important pathway for degassing
deeply buried sediments. Earth-Science Review 59, 49–76.
Etiope, G., Feyzullayev, A., Baciu, C.L., 2008. Terrestrial methane seeps and mud
volcanoes: a global perspective of gas origin. Marine and Petroleum Geology 26
(3), 333–344.
Fusi, N., Kenyon, N.H., 1996. Distribution of mud diapirism and other geological
structures from long range sidescan sonar (GLORIA) data, in the Eastern
Mediterranean Sea. Marine Geology 132, 21–38.
Gardiner, W., Grasso, M., Sedgeley, D., 1993. Plio-Pleistocene stratigraphy and fault
movement of the Malta platform. In: Max, M.D., Colantoni, P. (Eds.), UNESCO
Techical Reports in Marine Science, vol. 58, pp. 111–116.
Gardiner, W., Grasso, M., Sedgeley, D., 1995. Plio-Pleistocene fault movement as
evidence for megablock kinematics within the Hyblean–Malta Plateau, central
Mediterranean. Journal Geodynamics 19 (1), 35–51.
Ginsburg, G.D., Soloviev, V.A., 1994. Mud volcano gas hydrates in the Caspian Sea.
Bulletin of the Geological Society of Denmark 41, 95–100.
Henry, P., Le Pichon, X., Lallemant, S., Foucher, J.-P., Westbrook, G., Hobart, M.,
1990. Mud volcano field seaward of the Barbados accretionary complex:
a deep-towed side scan sonar survey. Journal of Geophysical Research 95,
8917–8929.
Holland, C.W., Etiope, G., Milkov, A.V., Michelozzi, E., Favali, P., 2003. Mud volcanoes
discovered offshore Sicily. Marine Geology 199, 1–6.
Holland, C.W.,Weber, T.C., Etiope, G., 2006. Acoustic scattering from mud volcanoes
and carbonate mounds. Journal Acoustical Society of America 120 (6),
3553–3565.
Hovland, M., Svensen, H., Forsberg, C.F., Johansen, H., Fichler, C., Fossa, J.H.,
Jonsson, R., Rueslatten, H., 2005. Complex pockmarks with carbonate-ridges off
mid-Norway: products of sediment degassing. Marine Geology 218 (1–4),
191–206.
Hovland, M., Judd, A.G., 1988. Seabed Pockmarks and Seepages: Impact on Geology,
Biology and Marine Environment. Graham and Trotman, London, 293 pp.
Incarbona, A., Bonomo, S., Di Stefano, E., Zgozi, S., Essarbout, N., Talha, M.,
Tranchida, G., Bonanno, A., Patti, B., Placenti, F., Buscaino, G., Cuttitta, A.,
Basilone, G., Bahri, T., Massa, F., Censi, P., Mazzola, S., 2008. Calcareous nannofossil
surface sediment assemblages from the Sicily Channel (central Mediterranean
Sea): paleoceanographic implications. Marine Micropaleontology 67,
255–273.
Ivanov, M.K., Limonov, A.F., van Weering, Tj.C.E., 1996. Comparative characteristics
of the Black Sea and Mediterranean ridge mud volcanoes. Marine Geology 132,
253–271.
Kopf, A.J., 2002. Significance of mud volcanism. Reviews of Geophysics 40 (2), 1–52.
Le Pichon, X., Foucher, J.-P., Boulegue, J., Henry, P., Lallemant, S., Benedetti, M.,
Avedik, F., Mariotti, A., 1990. Mud volcano field seaward of the Barbados
accretionary complex: a submersible survey. Journal of Geophysical Research
95, 8931–8943.
Lermusiaux, P.F.J., Robinson, A.R., 2001. Features of dominant mesoscale variability,
circulation patterns and dynamics in the Strait of Sicily. Deep-Sea Research I
Oceanographic Research Paper 48 (9), 1953–1997.
Loncke, L., Mascle, J., and the Fanil Scientific Party, 2004. Mud volcanoes, gas
chimneys, pock-marks and mounds in the Nile deep-sea fan (Eastern
Mediterranean): geophysical evidences. Marine and Petroleum Geology 21,
669–689.
Masson, D.G., Bett, B.J., Billett, D.S.M., Jacobs, C.L., Wheeler, A.J., Wynn, R.B., 2003.
The origin of deep-water, coral-topped mounds in the northern Rockall Trough,
Northeast Atlantic. Marine Geology 194, 159–180.
Matavalli, L., Novelli, L., 1990. Geochemistry and habitat of the oils of Italy. AAPG
Bulletin 74, 1623–1639.
Max, M.D., Kristensen, A., Michelozzi, E., 1993. Small scale Plio-Quaternary sequence
stratigraphy and shallow geology of the west-central Malta Plateau. In:
Max, M.D., Colantoni, P. (Eds.), UNESCO Techical Reports in Marine Science, vol.
58, pp. 117–122. Italy.
Mazzini, A., Svensen, H., Planke, S., Guliyev, I., Akhmanov, G.G., Fallik, T., Banks, D.,
2008. When mud volcanoes sleep: insight from seep geochemistry at the
Dashgil mud volcano, Azerbaijan. Marine and Petroleum Geology. doi:10.1016/
j.marpetgeo.2008.11.003.
Milkov, A.V., 2000. Worldwide distribution of submarine mud volcanoes and
associated gas hydrates. Marine Geology 167, 29–42.
Minisini, D., Trincardi, F., Asioli, A., Canuz, M., Foglini, F., 2007. Morphologic variability
of exposed mass-transport deposits on the eastern slope of Gela Basin
(Sicily channel). Basin Research 19, 217–240.
Neurauter, T.W., Bryant, W.R., 1990. Seismic expression of sedimentary volcanism
on the continental slope, Northern Gulf of Mexico. Geo-Marine Letters 10,
225–231.
Neurauter, T.W., Roberts, H.H., 1994. Three generation of mud volcanoes on the
Louisiana continental slope. Geo-Marine Letters 14, 120–125.
Orange, D., Hovland, M., Greene, H.G., 2001. The implications of hydrocarbon
seepage, gas migration and fluid overpressures to both exploration and geohazards
– from Frontier exploration to slope failure risk assessment. In: AAPG
Hedberg Conference ‘‘Near-Surface Hydrocarbon Migration: Mechanisms and
Seepage Rates’’, September 16–19, 2001, Vancouver, BC, Canada.
Osler, J., Algan, O., 1999. A High Resolution Seismic Sequence Analysis of the Malta
Plateau. Saclantcen Report serial no. SR-311.
Patacca, E., Scandone, P., Giunta, G., Liguori, V.,1979. Mesozoic paleotectonic evolution
of the Ragusa zone (Southeastern Sicily). Geologia Romana 18, 331–369.
Pedley, H.M., 1989. Syndepositional tectonics affecting Cenozoic and Mesozoic
deposition in the Malta and SE Sicily areas (Central Mediterranean) and their
bearing on Mesozoic reservoir development in the N Malta offshore region.
Marine and Petroleum Geology 7, 171–180.
Perch-Nielsen, K., 1985. Cenozoic calcareous nannofossils. In: Bolli, H.M.,
Saunders, J.B., Perch-Nielsen, K. (Eds.), Plankton Stratigraphy. Cambridge
University Press, Cambridge, pp. 427–554.
Planke, S., Svensen, H., Hovland, M., Banks, D., Jamtveit, B., 2003. Mud and fluid
migration in active mud volcanoes in Azerbaijan. Geo-Marine Letters 23, 258–268.
Prior, D.B., Coleman, J.M., 1984. Submarine slope instability. In: Brunsden, D.,
Prior, D.B. (Eds.), Slope Instability. Wiley, New York, pp. 419–455.
Roberts, H.H., Hardage, B.A., Shedd, W.W., Hunt, J.J., 2006. Seafloor reflectivitydan
important seismic property for interpreting fluid/gas expulsion geology and the
presence of gas hydrate. Leading Edge (Tulsa, OK) 25 (5), 620–628.
Sager,W.W., Macdonald, I.R., Hour, R., 2003. Geophysical signatures of mud mounds
at hydrocarbon seeps on the Louisiana continental slope, northern Gulf of
Mexico. Marine Geology 198 (1–2), 97–132.
Sautkin, A., Talukder, A.R., Comas, M.C., Soto, J.I., Alekseev, A., 2003. Mud volcanoes
in the Alboran Sea: evidence from micropaleontological and geophysical data.
Marine Geology 195, 237–261.
Savini, A., Corselli, C., Tessarolo, C., Daffonchio, D., Bellanca, A., Danovaro, R., Etiope,
G., 2007. Seafloor mapping and acoustic geophysical data of a shallow likely
mud-volcanoes province offshore Sicily (eastern Sicily Channel – Hyblean–
Malta plateau). 38 CIESM Congress, 09–13 April 2007, Istanbul.
Schramm, M.V., Livraga, G., 1986. Vega field and the potential of Ragusa basin,
offshore Sicily. In: Halbouty, M.T. (Ed.), Future Petroleum Provinces of the
World, Memoir 40. American Association of Petroleum Geologists, pp. 560–566.
Sprovieri, R., Di Stefano, E., Howell, M., Sakamoto, T., Di Stefano, A., Marino, M., 1998.
Integrated calcareous plankton biostratigraphy and ciclostratigraphy at Site
964. In: Robertson, A.H.F., Emeis, K.C., Richter, C., Camerlenghi, A. (Eds.),
Proceedings of the Ocean Drilling Program, Scientific Results, vol. 160, pp. 155–
165. College Station, Texas.
Sprovieri, R., Di Stefano, E., Incarbona, A., Gargano, M.E., 2003. A high-resolution
record of the last deglaciation in the Sicily Channel based on foraminifera and
calcareous nannofossils quantitative distribution. Paleogeography, Paleoclimatology,
Palaeoecology 202, 119–142.
Vai, G.B., Cantelli, L. (Eds.), 2004. Litho-palaeoenvironmental maps of Italy during
the last two climatic extremes. Map. 1 – Last Glacial Maximum; Map. 2 –
Holocene climatic optimum, 1:1.000.000 scale. 32nd I.G.C. Florence.
Vogt, P.R., Gardner, J., Crane, K., 1999. The Norwegian-Barents-Svalbard (NBS)
continental margin: introducing a natural laboratory of mass wasting, hydrates,
and ascent of sediment, pore water, and methane. Geo-Marine Letters 19, 2–21.
Yin, A., Berne´ , S., Loubrieu, B., Liu, Z., 2003. Mud volcanoes at the shelf margin of the
East China Sea. Marine Geology 194, 135–149.
Evolution of a section of the Africa–Europe plate boundary; paleomagnetic and
volcanological evidence from Sicily. Earth Planetary Science Letters 22 (2),
123–132.
Brown, K.M., 1990. Nature and hydrogeologic significance of mud diapirs and
diatremes for accretionary systems. Journal of Geophysical Research 95,
8969–8982.
Butler, R.W.H., 1997. Depositional patterns and their tectonic controls within the
Plio-Quaternary carbonate sand and muds of onshore and offshore SE Sicily
(Italy). Marine and Petroleum Geology 14 (7/8), 879–892.
Camerlenghi, A., Pini, G.A., 2009. Mud volcanoes, olistostromes and Argille scagliose
in the Mediterranean region. Sedimentology 56, 319–365.
Cangemi, M., Bellanca, A., Neri, R., Scopelliti, G., 2008. Biomineralization events in
Recent volcanic and sedimentary settings: textural features and isotope
signatures. In: 33rd International Geology Congress, Oslo 2008.
Castradori, D., 1993. Calcareous nannofossil biostratigraphy and biochronology in
eastern Mediterranean deep-sea cores. Rivista Italiana di Paleontologia e
Stratigrafia 99 (1), 107–126.
Ceramicola, S., Praeg, D., Wardell, N., Unnithan, V., 2007. Seismic imaging of mud
volcanoes on the Calabrian Arc accretionary prism, central Mediterranean Sea.
Eos, Transactions, American Geophysical Union 88 (52) SUPPL., Abstract V22C-
05, Dec 2007.
Cita, M.B., Ivanov, M.K.,Woodside, J.M., 1996. The Mediterranean Ridge Diapiric Belt.
Marine Geology 132, 1–6.
Dimitrov, L.I., 2002. Mud volcanoes - the most important pathway for degassing
deeply buried sediments. Earth-Science Review 59, 49–76.
Etiope, G., Feyzullayev, A., Baciu, C.L., 2008. Terrestrial methane seeps and mud
volcanoes: a global perspective of gas origin. Marine and Petroleum Geology 26
(3), 333–344.
Fusi, N., Kenyon, N.H., 1996. Distribution of mud diapirism and other geological
structures from long range sidescan sonar (GLORIA) data, in the Eastern
Mediterranean Sea. Marine Geology 132, 21–38.
Gardiner, W., Grasso, M., Sedgeley, D., 1993. Plio-Pleistocene stratigraphy and fault
movement of the Malta platform. In: Max, M.D., Colantoni, P. (Eds.), UNESCO
Techical Reports in Marine Science, vol. 58, pp. 111–116.
Gardiner, W., Grasso, M., Sedgeley, D., 1995. Plio-Pleistocene fault movement as
evidence for megablock kinematics within the Hyblean–Malta Plateau, central
Mediterranean. Journal Geodynamics 19 (1), 35–51.
Ginsburg, G.D., Soloviev, V.A., 1994. Mud volcano gas hydrates in the Caspian Sea.
Bulletin of the Geological Society of Denmark 41, 95–100.
Henry, P., Le Pichon, X., Lallemant, S., Foucher, J.-P., Westbrook, G., Hobart, M.,
1990. Mud volcano field seaward of the Barbados accretionary complex:
a deep-towed side scan sonar survey. Journal of Geophysical Research 95,
8917–8929.
Holland, C.W., Etiope, G., Milkov, A.V., Michelozzi, E., Favali, P., 2003. Mud volcanoes
discovered offshore Sicily. Marine Geology 199, 1–6.
Holland, C.W.,Weber, T.C., Etiope, G., 2006. Acoustic scattering from mud volcanoes
and carbonate mounds. Journal Acoustical Society of America 120 (6),
3553–3565.
Hovland, M., Svensen, H., Forsberg, C.F., Johansen, H., Fichler, C., Fossa, J.H.,
Jonsson, R., Rueslatten, H., 2005. Complex pockmarks with carbonate-ridges off
mid-Norway: products of sediment degassing. Marine Geology 218 (1–4),
191–206.
Hovland, M., Judd, A.G., 1988. Seabed Pockmarks and Seepages: Impact on Geology,
Biology and Marine Environment. Graham and Trotman, London, 293 pp.
Incarbona, A., Bonomo, S., Di Stefano, E., Zgozi, S., Essarbout, N., Talha, M.,
Tranchida, G., Bonanno, A., Patti, B., Placenti, F., Buscaino, G., Cuttitta, A.,
Basilone, G., Bahri, T., Massa, F., Censi, P., Mazzola, S., 2008. Calcareous nannofossil
surface sediment assemblages from the Sicily Channel (central Mediterranean
Sea): paleoceanographic implications. Marine Micropaleontology 67,
255–273.
Ivanov, M.K., Limonov, A.F., van Weering, Tj.C.E., 1996. Comparative characteristics
of the Black Sea and Mediterranean ridge mud volcanoes. Marine Geology 132,
253–271.
Kopf, A.J., 2002. Significance of mud volcanism. Reviews of Geophysics 40 (2), 1–52.
Le Pichon, X., Foucher, J.-P., Boulegue, J., Henry, P., Lallemant, S., Benedetti, M.,
Avedik, F., Mariotti, A., 1990. Mud volcano field seaward of the Barbados
accretionary complex: a submersible survey. Journal of Geophysical Research
95, 8931–8943.
Lermusiaux, P.F.J., Robinson, A.R., 2001. Features of dominant mesoscale variability,
circulation patterns and dynamics in the Strait of Sicily. Deep-Sea Research I
Oceanographic Research Paper 48 (9), 1953–1997.
Loncke, L., Mascle, J., and the Fanil Scientific Party, 2004. Mud volcanoes, gas
chimneys, pock-marks and mounds in the Nile deep-sea fan (Eastern
Mediterranean): geophysical evidences. Marine and Petroleum Geology 21,
669–689.
Masson, D.G., Bett, B.J., Billett, D.S.M., Jacobs, C.L., Wheeler, A.J., Wynn, R.B., 2003.
The origin of deep-water, coral-topped mounds in the northern Rockall Trough,
Northeast Atlantic. Marine Geology 194, 159–180.
Matavalli, L., Novelli, L., 1990. Geochemistry and habitat of the oils of Italy. AAPG
Bulletin 74, 1623–1639.
Max, M.D., Kristensen, A., Michelozzi, E., 1993. Small scale Plio-Quaternary sequence
stratigraphy and shallow geology of the west-central Malta Plateau. In:
Max, M.D., Colantoni, P. (Eds.), UNESCO Techical Reports in Marine Science, vol.
58, pp. 117–122. Italy.
Mazzini, A., Svensen, H., Planke, S., Guliyev, I., Akhmanov, G.G., Fallik, T., Banks, D.,
2008. When mud volcanoes sleep: insight from seep geochemistry at the
Dashgil mud volcano, Azerbaijan. Marine and Petroleum Geology. doi:10.1016/
j.marpetgeo.2008.11.003.
Milkov, A.V., 2000. Worldwide distribution of submarine mud volcanoes and
associated gas hydrates. Marine Geology 167, 29–42.
Minisini, D., Trincardi, F., Asioli, A., Canuz, M., Foglini, F., 2007. Morphologic variability
of exposed mass-transport deposits on the eastern slope of Gela Basin
(Sicily channel). Basin Research 19, 217–240.
Neurauter, T.W., Bryant, W.R., 1990. Seismic expression of sedimentary volcanism
on the continental slope, Northern Gulf of Mexico. Geo-Marine Letters 10,
225–231.
Neurauter, T.W., Roberts, H.H., 1994. Three generation of mud volcanoes on the
Louisiana continental slope. Geo-Marine Letters 14, 120–125.
Orange, D., Hovland, M., Greene, H.G., 2001. The implications of hydrocarbon
seepage, gas migration and fluid overpressures to both exploration and geohazards
– from Frontier exploration to slope failure risk assessment. In: AAPG
Hedberg Conference ‘‘Near-Surface Hydrocarbon Migration: Mechanisms and
Seepage Rates’’, September 16–19, 2001, Vancouver, BC, Canada.
Osler, J., Algan, O., 1999. A High Resolution Seismic Sequence Analysis of the Malta
Plateau. Saclantcen Report serial no. SR-311.
Patacca, E., Scandone, P., Giunta, G., Liguori, V.,1979. Mesozoic paleotectonic evolution
of the Ragusa zone (Southeastern Sicily). Geologia Romana 18, 331–369.
Pedley, H.M., 1989. Syndepositional tectonics affecting Cenozoic and Mesozoic
deposition in the Malta and SE Sicily areas (Central Mediterranean) and their
bearing on Mesozoic reservoir development in the N Malta offshore region.
Marine and Petroleum Geology 7, 171–180.
Perch-Nielsen, K., 1985. Cenozoic calcareous nannofossils. In: Bolli, H.M.,
Saunders, J.B., Perch-Nielsen, K. (Eds.), Plankton Stratigraphy. Cambridge
University Press, Cambridge, pp. 427–554.
Planke, S., Svensen, H., Hovland, M., Banks, D., Jamtveit, B., 2003. Mud and fluid
migration in active mud volcanoes in Azerbaijan. Geo-Marine Letters 23, 258–268.
Prior, D.B., Coleman, J.M., 1984. Submarine slope instability. In: Brunsden, D.,
Prior, D.B. (Eds.), Slope Instability. Wiley, New York, pp. 419–455.
Roberts, H.H., Hardage, B.A., Shedd, W.W., Hunt, J.J., 2006. Seafloor reflectivitydan
important seismic property for interpreting fluid/gas expulsion geology and the
presence of gas hydrate. Leading Edge (Tulsa, OK) 25 (5), 620–628.
Sager,W.W., Macdonald, I.R., Hour, R., 2003. Geophysical signatures of mud mounds
at hydrocarbon seeps on the Louisiana continental slope, northern Gulf of
Mexico. Marine Geology 198 (1–2), 97–132.
Sautkin, A., Talukder, A.R., Comas, M.C., Soto, J.I., Alekseev, A., 2003. Mud volcanoes
in the Alboran Sea: evidence from micropaleontological and geophysical data.
Marine Geology 195, 237–261.
Savini, A., Corselli, C., Tessarolo, C., Daffonchio, D., Bellanca, A., Danovaro, R., Etiope,
G., 2007. Seafloor mapping and acoustic geophysical data of a shallow likely
mud-volcanoes province offshore Sicily (eastern Sicily Channel – Hyblean–
Malta plateau). 38 CIESM Congress, 09–13 April 2007, Istanbul.
Schramm, M.V., Livraga, G., 1986. Vega field and the potential of Ragusa basin,
offshore Sicily. In: Halbouty, M.T. (Ed.), Future Petroleum Provinces of the
World, Memoir 40. American Association of Petroleum Geologists, pp. 560–566.
Sprovieri, R., Di Stefano, E., Howell, M., Sakamoto, T., Di Stefano, A., Marino, M., 1998.
Integrated calcareous plankton biostratigraphy and ciclostratigraphy at Site
964. In: Robertson, A.H.F., Emeis, K.C., Richter, C., Camerlenghi, A. (Eds.),
Proceedings of the Ocean Drilling Program, Scientific Results, vol. 160, pp. 155–
165. College Station, Texas.
Sprovieri, R., Di Stefano, E., Incarbona, A., Gargano, M.E., 2003. A high-resolution
record of the last deglaciation in the Sicily Channel based on foraminifera and
calcareous nannofossils quantitative distribution. Paleogeography, Paleoclimatology,
Palaeoecology 202, 119–142.
Vai, G.B., Cantelli, L. (Eds.), 2004. Litho-palaeoenvironmental maps of Italy during
the last two climatic extremes. Map. 1 – Last Glacial Maximum; Map. 2 –
Holocene climatic optimum, 1:1.000.000 scale. 32nd I.G.C. Florence.
Vogt, P.R., Gardner, J., Crane, K., 1999. The Norwegian-Barents-Svalbard (NBS)
continental margin: introducing a natural laboratory of mass wasting, hydrates,
and ascent of sediment, pore water, and methane. Geo-Marine Letters 19, 2–21.
Yin, A., Berne´ , S., Loubrieu, B., Liu, Z., 2003. Mud volcanoes at the shelf margin of the
East China Sea. Marine Geology 194, 135–149.
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