Did geologic emissions of methane play any role in Quaternary climate change?
Language
English
Obiettivo Specifico
3.8. Geofisica per l'ambiente
Status
Published
JCR Journal
JCR Journal
Peer review journal
Yes
Journal
Issue/vol(year)
1-2 / 61 (2008)
Publisher
Elsevier
Pages (printed)
79-88
Date Issued
2008
Alternative Location
Abstract
The “methane-led hypotheses” assume that gas hydrates and marine seeps are the sole geologic factors controlling Quaternary atmospheric and climate changes. Nevertheless, a wider class of geologic sources of methane exist which could have played a role in past climate changes. Beyond
offshore seepage, relevant geologic emissions of methane (GEM) are from onshore seepage, including mud volcanism, microseepage and
geothermal flux; altogether GEM are the second most important natural source of atmospheric methane at present. The amount of methane entering the atmosphere from onshore GEM seems to prevail on that from offshore seepage. Onshore sources inject a predominantly isotopically heavy (13C-enriched) methane into the atmosphere. They are controlled mainly by endogenic (geodynamic) processes, which induce large-scale gas flow variations over geologic and millennial time scales, and only partially by exogenic (surface) conditions, so that they are not affected by negative feedbacks. The eventual influence on atmospheric methane concentration does not necessarily require catastrophic or abrupt releases, as proposed for the “clathrate gun hypothesis”. Enhanced degassing from these sources could have contributed to the methane trends observed in the ice core records, and could explain the late Quaternary peaks of increased methane concentrations accompanied by the enrichment of isotopically heavy methane, as recently observed. This hypothesis shall be tested by means of robust multidisciplinary studies, mainly based on a series of atmospheric, biologic and geologic proxies.
offshore seepage, relevant geologic emissions of methane (GEM) are from onshore seepage, including mud volcanism, microseepage and
geothermal flux; altogether GEM are the second most important natural source of atmospheric methane at present. The amount of methane entering the atmosphere from onshore GEM seems to prevail on that from offshore seepage. Onshore sources inject a predominantly isotopically heavy (13C-enriched) methane into the atmosphere. They are controlled mainly by endogenic (geodynamic) processes, which induce large-scale gas flow variations over geologic and millennial time scales, and only partially by exogenic (surface) conditions, so that they are not affected by negative feedbacks. The eventual influence on atmospheric methane concentration does not necessarily require catastrophic or abrupt releases, as proposed for the “clathrate gun hypothesis”. Enhanced degassing from these sources could have contributed to the methane trends observed in the ice core records, and could explain the late Quaternary peaks of increased methane concentrations accompanied by the enrichment of isotopically heavy methane, as recently observed. This hypothesis shall be tested by means of robust multidisciplinary studies, mainly based on a series of atmospheric, biologic and geologic proxies.
References
Aliyev, A.A., Guliyev, I.S., Belov, I.S., 2002. Catalogue of Recorded Eruptions
of Mud Volcanoes of Azerbaijan. Pub. House “Nafta-Press”, Baku. 89 pp.
Blunier, T., Brook, E., 2001. Timing of millennial-scale climate changes in
Antarctica and Greenland during the last glacial period. Science 291,
109–112.
Brook, E., Sowers, T., Orchardo, J., 1996. Rapid variations in atmospheric methane
concentration during the past 110,000 years. Science 273, 1087–1091.
Cannariato, K.G., Stott, L.D., 2004. Evidence against clathrate-derived methane
release to Santa Barbara Basin surface waters? Geochem. Geophys.
Geosystem 5, Q05007. doi:10.1029/2003GC000600.
Chappellaz, J., Barnola, J.M., Raynaud, D., Korotkevich, Y.S., Lorius, C., 1990.
Ice-core record of atmospheric methane over the past 160,000 years. Nature
345, 127–131.
Chappellaz, J., Fung, I.Y., Thompson, A.M., 1993. The atmospheric CH4 increase
since the Last Glacial Maximum (1) Source estimates. Tellus 45B, 228–241.
Charlou, J.L., Donval, J.P., Zitter, T., Roy, N., Jean-Baptiste, P., Foucher, J.P.,
Woodside, J., MEDINAUT Scientific Party, 2003. Evidence of methane
venting and geochemistry of brines on mud volcanoes of the eastern
Mediterranean Sea. Deep-Sea Res. 50 (8), 941–958.
Clarke, R.H., Cleverly, R.W., 1991. Petroleum seepage and post-accumulation
migration. In: England, W.A., Fleet, A.J. (Eds.), Petroleum Migration. .
Geological Society Special Publication, vol. 59. Geological Society of
London, Bath, pp. 265–271.
Crutzen, P.J., 1991. Methane's sinks and sources. Nature 350, 380–381.
Crutzen, P.J., Bruhl, C., 1993. A model study of atmospheric temperatures and
the concentrations of ozone, hydroxyl, and some other photochemically
active gases during the glacial, the preindustrial Holocene and the present.
Geophys. Res. Lett. 20, 1047–1050.
Dadashev, A.A., Guliyev, I.S., 1989. Isotope Composition of Carbon in
Methane of Azerbaijan MVas Indicator of Gas Formation and Preservation
into Subsuface of South Caspian Basin. Izvestiya Akademii Nauk Azerb.
SSR, Seriya nauk o Zemle, vol. 1, pp. 7–12 (in Russian).
Dia, A.N., Castrec, M., Boulegue, J., Comeau, P., 1999. Trinidad mud
volcanoes: where do the expelled fluids come from? Geochim. Cosmochim.
Acta 63 (7/8), 1023–1038.
Dickens, G.R., Paull, C.K., Wallace, P., ODP Leg 164 Scientific Party, 1997.
Direct measurement of in situ methane quantities in a large gas-hydrate
reservoir. Nature 385, 426–428.
Dimitrov, L., 2002. Mud volcanoes — the most important pathway for
degassing deeply buried sediments. Earth-Sci. Rev. 59, 49–76.
Dimitrov, L., 2003. Mud volcanoes — a significant source of atmospheric
methane. Geo Mar. Lett 23, 155–161.
EEA, 2004. Joint EMEP/CORINAIR Atmospheric Emission Inventory Guidebook,
4th Ed. European Environment Agency, Copenhagen. Available at
http://reports.eea.eu.int/EMEPCORINAIR4/en.
Etiope, G., 2004. GEM—Geologic Emissions of Methane, the missing source
in the atmospheric methane budget. Atmos. Environ. 38 (19), 3099–3100.
Etiope, G., 2006. Evaluation of geological emissions of methane in Europe.
Contribution for the NATAIR Project. . NATAIR project report, EU contract
no. 513699, Institute of Energy Economics and the Rational Use of
EnergyUniversity of Stuttgart. 20 pp.
Etiope, G., Klusman, R.W., 2002. Geologic emissions of methane to the
atmosphere. Chemosphere 49, 777–789.
Etiope, G., Martinelli, G., 2002. Migration of carrier and trace gases in
the geosphere: an overview. Phys. Earth Planet. Inter. 129 (3–4),
185–204.
Etiope, G., Milkov, A.V., 2004. A new estimate of global methane flux from
onshore and shallow submarine mud volcanoes to the atmosphere. Environ.
Geol. 46, 997–1002.
Etiope, G., Klusman, R.W., in press. Microseepage in drylands: flux and
implications in the global atmospheric source/sink budget of methane.
Global Planet. Change.
Etiope, G., Feyzullaiev, A., Baciu, C.L., Milkov, A.V., 2004. Methane emission
from mud volcanoes in eastern Azerbaijan. Geology 32 (6), 465–468.
Etiope, G., Papatheodorou, G., Christodoulou, D., Ferentinos, G., Sokos, E.,
Favali, P., 2006. Methane and hydrogen sulfide seepage in the NW
Peloponnesus petroliferous basin (Greece): origin and geohazard. AAPG
Bull. 90 (5), 701–713.
Etiope, G., Martinelli, G., Caracausi, A., Italiano, F., 2007. Methane seeps and
mud volcanoes in Italy: gas origin, fractionation and emission to the
atmosphere. Geophys. Res. Lett. 34, L14303. doi:10.1029/2007GL030341.
Fowler, S.R., Mildenhall, J., Zalova, S., 2000. Mud volcanoes and structural
development on Shah Deniz. J. Pet. Sci. Eng. 28, 189–206.
Ginsburg, G.D., Milkov, A.V., Soloviev, V.A., Egorov, A.V., Cherkashev, G.A.,
Vogt, P.R., Crane, K., Lorenson, T.D., Khutorskoy, M.D., 1999. Gas hydrate
accumulation at the Haakon Mosby mud volcano. Geo Mar. Lett. 19, 57–67.
Gold, T., Soter, S., 1985. Fluid ascent through the solid lithosphere and its
relation to earthquakes. PAGEOPH 122, 492–530.
Greinert, J., Bohrmann, G., Suess, E., 2001. Methane venting and gas hydraterelated
carbonates at the hydrate ridge: their classification, distribution and
origin. In: Paull, C.K., Dillon,W.P. (Eds.), Natural Gas Hydrates: Occurrence,
Distribution, and Detection. Geopohysical Monograph, vol. 124, pp. 99–113.
Guliyev, I.S., Feyzullayev, A.A., 1997. All about mud volcanoes. Baku Pub.
House, NAFTA-Press, 120 pp.
Hensen, C., Wallmann, K., Schmidt, M., Ranero, C.R., Suess, E., 2004. Fluid
expulsion related to mud extrusion off Costa Rica—a window to the
subducting slab. Geology 32, 201–204.
Hinrichs,K.-U.,Hmelo, L.R., Sylva, S.P., 2003.Molecular fossil record of elevated
methane levels in Late Pleistocene coastal waters. Science 299, 1214–1217.
Hornafius, J.S., Quigley, D., Luyendyk, B.P., 1999. The world's most
spectacular marine hydrocarbon seeps (Coal Oil Point, Santa Barbara
Channel, California): quantification of emissions. J. Geophys. Res. 104,
20703–20711.
Hovland, M., Judd, A.G., 1988. Seabed Pockmarks and Seepages: Impact on
Geology, Biology, and theMarine Environment. Graham& Trotman, London.
Hunt, J.M., 1996. Petroleum Geochemistry and Geology. W.H. Freeman and
Co., New York. 743 pp.
Huseynov, D.A., Guliyev, I.S., 2004. Mud volcanic natural phenomena in the
South Caspian Basin: geology, fluid dynamics and environmental impact.
Environ. Geol. 46, 1012–1023.
Intergovernmental Panel on Climate Change, 2001. In: Houghton, J.T., Ding, Y.,
Griggs, D.J., Noguer, M., van der Linden, P.J., Dai, X., Maskell, K.,
Johnson, C.A. (Eds.), Climate Change 2001: The Scientific Basis.
Cambridge Univ. Press, Cambridge, UK. 881 pp.
Jones, V.T., Drozd, R.J., 1983. Predictions of oil or gas potential by near-surface
geochemistry. AAPG Bull. 67, 932–952.
Judd, A.G., Charlier, R.H., Lacroix, A., Lambert, G., Rouland, C., 1993. Minor
sources of methane. In: Khalil, M.A.K. (Ed.), Atmospheric Methane: Sources, Sinks and Role in Global Change. Springer-Verlag, Berlin
Heidelberg, pp. 432–456.
Judd, A.G., Hovland, M., Dimitrov, L.I., Garcia Gil, S., Jukes, V., 2002. The
geological methane budget at Continental Margins and its influence on
climate change. Geofluids 2, 109–126.
Kennett, J.P., Cannariato, K.G., Hendy, I.L., Behl, R.J., 2003. Methane hydrates
in Quaternary climate change. The Clathrate Gun Hypothesis. American
Geophysical Union, Washington, DC, p. 216.
Klusman, R.W., Jakel, M.E., LeRoy, M.P., 1998. Does microseepage of methane
and light hydrocarbons contribute to the atmospheric budget of methane and
to global climate change? Assoc. Petrol. Geochem. Explor. Bull. 11, 1–55.
Klusman, R.W., Leopold, M.E., LeRoy, M.P., 2000. Seasonal variation in
methane fluxes from sedimentary basins to the atmosphere: results from
chamber measurements and modeling of transport from deep sources. J.
Geophys. Res. 105D, 24,661–24,670.
Kvenvolden, K.A., 1988. Methane hydrates—a major reservoir of caron in the
shallow geosphere? Chem. Geol. 71, 41–51.
Kvenvolden, K.A., Rogers, B.W., 2005. Gaia's breath — global methane
exhalations. Mar. Petrol. Geol. 22, 579–590.
Kvenvolden, K.A., Lorenson, T.D., Reeburgh, W., 2001. Attention turns to
naturally occurring methane seepage. EOS 82, 457.
Lacroix, A.V., 1993. Unaccounted-for sources of fossil and isotopically enriched
methane and their contribution to the emissions inventory: a review and
synthesis. Chemosphere 26, 507–557.
Lavrushin, V.Y., Polyak, B.G., Prasolov, R.M., Kamenskii, I.L., 1996. Sources
of material in mud volcano products (based on isotopic, hydrochmical and
geological data). Lithos Miner. Res. 31, 557–578.
Leifer, I., Patro, R.K., 2002. The bubble mechanism for methane transport from
the shallow sea bed to the surface: a review and sensitivity study. Cont. Shelf
Res. 22 (16), 2409–2428.
Lelieveld, J., Crutzen, P.J., Dentener, F.J., 1998. Changing concentration,
lifetime and climate forcing of atmospheric methane. Tellus 50B, 128–150.
Link, W.K., 1952. Significance of oil and gas seeps in world oil exploration.
AAPG Bull. 36, 1505–1540.
Luyendyk, B., Kennett, J., Clark, J.F., 2005. Hypothesis for increased
atmospheric methane input from hydrocarbon seeps on exposed continental
shelves during glacial low sea level. Mar. Petrol. Geol. 22, 591–596.
Macgregor, D.S., 1993. Relationships between seepage, tectonics and subsurface
petroleum reserves. Mar. Pet. Geol. 10, 606–619.
Maslin, M.A., Thomas, E., 2003. Balancing the deglacial global carbon budget;
the hydrate factor. Quat. Sci. Rev. 22, 1729–1736.
Milkov, A.V., 2000. Worldwide distribution of submarine mud volcanoes and
associated gas hydrates. Mar. Geol. 167, 29–42.
Milkov, A.V., 2004. Global estimates of hydrate-bound gas in marine sediments:
How much is really out there? Earth-Sci. Rev. 66, 183–197.
Milkov, A.V., 2005. Molecular and stable isotope compositions of natural gas
hydrates: A revised global dataset and basic interpretations in the context of
geological settings. Org. Geochem. 36, 681–702.
Milkov, A.V., Sassen, R., 2002. Economic geology of offshore gas hydrate
accumulations and provinces. Mar. Pet. Geol. 19, 1–11.
Milkov, A.V., Sassen, R., 2003. Two-dimensional modeling of gas hydrate
decomposition in the northwestern Gulf of Mexico: significance to global
change assessment. Glob. Planet. Change 36, 31–46.
Milkov, A.V., Claypool, G.E., Lee, Y.-J., Dickens, G.R., Xu, W., Borowski, W.
S., ODP Leg 204 Scientific Party, 2003a. In situ methane concentrations at
Hydrate Ridge offshore Oregon: new constraints on the global gas hydrate
inventory from an active margin. Geology 31, 833–836.
Milkov, A.V., Sassen, R., Apanasovich, T.V., Dadashev, F.G., 2003b. Global gas
flux from mud volcanoes: a significant source of fossil methane in the
atmosphere and the ocean. Geophys. Res. Lett. 30 (2), 1037. doi:10.1029/
2002GL016358.
Milkov, A.V., Vogt, P.R., Crane, K., Lein, A.Yu., Sassen, R., Cherkashev, G.A.,
2004. Geological, geochemical, and microbial processes at the hydratebearing
Håkon Mosby mud volcano: a review. Chem. Geol. 205, 347–366.
Morner, N.A., 1978. Faulting, fracturing and seismicity as functions of glacioisostasy
in Fennoscandia. Geology 6, 41–45.
Morner, N.A., Etiope, G., 2002. Carbon degassing from the lithosphere. Glob.
Planet. Change 33 (1–2), 185–203.
Nisbet, E.G., 2002. Have sudden large releases of methane from geological
reservoirs occurred since the Last Glacial Maximum, and could such
releases occur again? Philos. Trans. R. Soc. Lond. 360, 581–607.
Pentecost, A., 1995. The Quaternary travertine deposits of Europe and Asia
Minor. Quat. Sci. Rev. 14, 1005–1028.
Petit, J.R., Jouzel, J., Raynaud, D., Barkov, N.I., Barnola, J.M., Basile, I.,
Bender, M., Chappellaz, J., Davis, M., Delaygue, G., Delmotte, M.,
Kotlyakov, V.M., Legrand, M., Lipenkov, V.Y., Lorius, C., Pepin, L., Ritz,
C., Saltzman, E., Stievenard, M., 1999. Climate and atmospheric history of
the past 420,000 years from the Vostok ice core, Antarctica. Nature 399,
429–436.
Planke, S., Svensen, H., Hovland, M., Banks, D.A., Jamtveit, B., 2003. Mud and
fluid migration in active mud volcanoes in Azerbaijan. Geo Mar. Lett. 23,
258–268.
Quay, P., Stutsman, J., Wilbur, D., Snover, A., Dlugokencky, E., Brown, T.,
1999. The isotopic composition of atmospheric methane. Glob. Biogeochem.
Cycles 13, 445–461.
Quigley, D.C., Hornafius, J.S., Luyendyk, B.P., Francis, R.D., Clark, J.,
Washburn, L., 1999. Decrease in natural marine hydrocarbon seepage near
Coal Oil Point, California, associated with offshore oil production. Geology
27, 1047–1050.
Revil, A., 2002. Genesis of mud volcanoes in sedimentary basins: a solitary wavebased
mechanism. Geophys. Res. Lett. 29, 12. doi:10.1029/2001GL014465.
Schaefer, H., Whiticar, M.J., Brook, E.J., Petrenko, V.V., Ferretti, D.F.,
Severinghaus, J.P., 2006. Ice record of d13C for atmospheric CH4 across
the Younger Dryas–Preboreal transition. Science 313, 1109–1112.
Sowers, T.A., 2000. The δ13C of atmospheric CH4 over the past 30,000 years as
recorded in the Taylor Dome ice core. Eos Trans. AGU 81 (48) (Fall Meet.
Suppl., Abstract A62A-04, 2000).
Sowers, T., 2006. Late Quaternary atmospheric CH4 isotope record suggests
marine clathrates are stable. Science 311, 838–840.
Stewart, I., Sauber, J., Rose, J., 2000. Glacio-seismotectonics: ice sheets, crustal
deformation and seismicity. Quat. Sci. Rev. 19, 1367–1389.
Svensen, H., Planke, S., Jamtveit, B., Pedersen, T., 2003. Seep carbonate
formation controlled by hydrothermal vent complexes: a case study from the
Vøring volcanic basin, the Norwegian Sea. Geo Mar. Lett. 23, 351–358.
Svensen, H., Planke, S., Malthe-Sørenssen, A., Jamtveit, B., Myklebust, R.,
Eidem, T., Rey, S.S., 2004. Release of methane from a volcanic basin as a
mechanism for initial Eocene global warming. Nature 429, 542–545.
Taviani, M., 2001. Fluid venting and associated processes. In: Vai, G.B.,
Martini, I.P. (Eds.), Anatomy of an Orogen: The Apennines and Adjacent
Mediterranean Basins. KluwerAcademic, Dordrecht, pp. 351–366.
Terzi, C., Aharon, P., Ricci Lucchi, F., Vai, G.B., 1994. Petrography and stable
isotope aspects of cold-vent activity imprinted on Miocene-age ‘calcari a
Lucina’ from Tuscana and Romagna Apennines, Italy. Geo Mar. Lett. 14,
177–184.
Thompson, A.M., Chappellaz, J.A., Fung, I.Y., Kucsera, T.L., 1993. The
atmospheric CH4 increase since the Last Glacial Maximum (2). Interactions
with oxidants. Tellus 45B, 242–257.
Torgersen, T., O'Donnell, J., 1991. The degassing flux from the solid earth:
release by fracturing. Geophys. Res. Lett. 18 (5), 951–954.
Torres, M.E., Mix, A.C., Kinports, K., Haley, B., Klinkhammer, G.P.,
McManus, J., de Angelis, M.A., 2003. Is methane venting at the seafloor
recorded by d13C of benthic foraminifera shells? Paleoceanography 18 (3),
1062. doi:10.1029/2002PA000824.
Tyler, S.C.,Ajie,H.O.,Gupta,M.L., Cicerone,R.J.,Blacke,D.R.,Dlugokencky, E.
J., 1999. Carbon isotopic composition of atmospheric methane: a comparison
of surface level and upper tropospheric air. J. Geophys. Res. 104,
13,895–13,910.
Valentine, D.L., Blanton, D.C., Reeburgh, W.S., Kastner, M., 2001. Water
column methane oxidation adjacent to an area of active hydrate dissociation,
Eel river Basin. Geochim. Cosmochim. Acta 65, 2633–2640.
Wu, P., Johnston, P., Lambeck, K., 1999. Postglacial rebound and fault
instability in Fennoscandia. Geophys. J. Int. 139, 657–670.
Wuebbles, D.J., Hayhoe, K., 2002. Atmospheric methane and global change.
Earth-Sci. Rev. 57, 177–210.
Yusifov, M., Rabinowitz, P.D., 2004. Classification of mud volcanoes in the
South Caspian Basin, offshore Azerbaijan. Mar. Pet. Geol. 21, 965–975.
of Mud Volcanoes of Azerbaijan. Pub. House “Nafta-Press”, Baku. 89 pp.
Blunier, T., Brook, E., 2001. Timing of millennial-scale climate changes in
Antarctica and Greenland during the last glacial period. Science 291,
109–112.
Brook, E., Sowers, T., Orchardo, J., 1996. Rapid variations in atmospheric methane
concentration during the past 110,000 years. Science 273, 1087–1091.
Cannariato, K.G., Stott, L.D., 2004. Evidence against clathrate-derived methane
release to Santa Barbara Basin surface waters? Geochem. Geophys.
Geosystem 5, Q05007. doi:10.1029/2003GC000600.
Chappellaz, J., Barnola, J.M., Raynaud, D., Korotkevich, Y.S., Lorius, C., 1990.
Ice-core record of atmospheric methane over the past 160,000 years. Nature
345, 127–131.
Chappellaz, J., Fung, I.Y., Thompson, A.M., 1993. The atmospheric CH4 increase
since the Last Glacial Maximum (1) Source estimates. Tellus 45B, 228–241.
Charlou, J.L., Donval, J.P., Zitter, T., Roy, N., Jean-Baptiste, P., Foucher, J.P.,
Woodside, J., MEDINAUT Scientific Party, 2003. Evidence of methane
venting and geochemistry of brines on mud volcanoes of the eastern
Mediterranean Sea. Deep-Sea Res. 50 (8), 941–958.
Clarke, R.H., Cleverly, R.W., 1991. Petroleum seepage and post-accumulation
migration. In: England, W.A., Fleet, A.J. (Eds.), Petroleum Migration. .
Geological Society Special Publication, vol. 59. Geological Society of
London, Bath, pp. 265–271.
Crutzen, P.J., 1991. Methane's sinks and sources. Nature 350, 380–381.
Crutzen, P.J., Bruhl, C., 1993. A model study of atmospheric temperatures and
the concentrations of ozone, hydroxyl, and some other photochemically
active gases during the glacial, the preindustrial Holocene and the present.
Geophys. Res. Lett. 20, 1047–1050.
Dadashev, A.A., Guliyev, I.S., 1989. Isotope Composition of Carbon in
Methane of Azerbaijan MVas Indicator of Gas Formation and Preservation
into Subsuface of South Caspian Basin. Izvestiya Akademii Nauk Azerb.
SSR, Seriya nauk o Zemle, vol. 1, pp. 7–12 (in Russian).
Dia, A.N., Castrec, M., Boulegue, J., Comeau, P., 1999. Trinidad mud
volcanoes: where do the expelled fluids come from? Geochim. Cosmochim.
Acta 63 (7/8), 1023–1038.
Dickens, G.R., Paull, C.K., Wallace, P., ODP Leg 164 Scientific Party, 1997.
Direct measurement of in situ methane quantities in a large gas-hydrate
reservoir. Nature 385, 426–428.
Dimitrov, L., 2002. Mud volcanoes — the most important pathway for
degassing deeply buried sediments. Earth-Sci. Rev. 59, 49–76.
Dimitrov, L., 2003. Mud volcanoes — a significant source of atmospheric
methane. Geo Mar. Lett 23, 155–161.
EEA, 2004. Joint EMEP/CORINAIR Atmospheric Emission Inventory Guidebook,
4th Ed. European Environment Agency, Copenhagen. Available at
http://reports.eea.eu.int/EMEPCORINAIR4/en.
Etiope, G., 2004. GEM—Geologic Emissions of Methane, the missing source
in the atmospheric methane budget. Atmos. Environ. 38 (19), 3099–3100.
Etiope, G., 2006. Evaluation of geological emissions of methane in Europe.
Contribution for the NATAIR Project. . NATAIR project report, EU contract
no. 513699, Institute of Energy Economics and the Rational Use of
EnergyUniversity of Stuttgart. 20 pp.
Etiope, G., Klusman, R.W., 2002. Geologic emissions of methane to the
atmosphere. Chemosphere 49, 777–789.
Etiope, G., Martinelli, G., 2002. Migration of carrier and trace gases in
the geosphere: an overview. Phys. Earth Planet. Inter. 129 (3–4),
185–204.
Etiope, G., Milkov, A.V., 2004. A new estimate of global methane flux from
onshore and shallow submarine mud volcanoes to the atmosphere. Environ.
Geol. 46, 997–1002.
Etiope, G., Klusman, R.W., in press. Microseepage in drylands: flux and
implications in the global atmospheric source/sink budget of methane.
Global Planet. Change.
Etiope, G., Feyzullaiev, A., Baciu, C.L., Milkov, A.V., 2004. Methane emission
from mud volcanoes in eastern Azerbaijan. Geology 32 (6), 465–468.
Etiope, G., Papatheodorou, G., Christodoulou, D., Ferentinos, G., Sokos, E.,
Favali, P., 2006. Methane and hydrogen sulfide seepage in the NW
Peloponnesus petroliferous basin (Greece): origin and geohazard. AAPG
Bull. 90 (5), 701–713.
Etiope, G., Martinelli, G., Caracausi, A., Italiano, F., 2007. Methane seeps and
mud volcanoes in Italy: gas origin, fractionation and emission to the
atmosphere. Geophys. Res. Lett. 34, L14303. doi:10.1029/2007GL030341.
Fowler, S.R., Mildenhall, J., Zalova, S., 2000. Mud volcanoes and structural
development on Shah Deniz. J. Pet. Sci. Eng. 28, 189–206.
Ginsburg, G.D., Milkov, A.V., Soloviev, V.A., Egorov, A.V., Cherkashev, G.A.,
Vogt, P.R., Crane, K., Lorenson, T.D., Khutorskoy, M.D., 1999. Gas hydrate
accumulation at the Haakon Mosby mud volcano. Geo Mar. Lett. 19, 57–67.
Gold, T., Soter, S., 1985. Fluid ascent through the solid lithosphere and its
relation to earthquakes. PAGEOPH 122, 492–530.
Greinert, J., Bohrmann, G., Suess, E., 2001. Methane venting and gas hydraterelated
carbonates at the hydrate ridge: their classification, distribution and
origin. In: Paull, C.K., Dillon,W.P. (Eds.), Natural Gas Hydrates: Occurrence,
Distribution, and Detection. Geopohysical Monograph, vol. 124, pp. 99–113.
Guliyev, I.S., Feyzullayev, A.A., 1997. All about mud volcanoes. Baku Pub.
House, NAFTA-Press, 120 pp.
Hensen, C., Wallmann, K., Schmidt, M., Ranero, C.R., Suess, E., 2004. Fluid
expulsion related to mud extrusion off Costa Rica—a window to the
subducting slab. Geology 32, 201–204.
Hinrichs,K.-U.,Hmelo, L.R., Sylva, S.P., 2003.Molecular fossil record of elevated
methane levels in Late Pleistocene coastal waters. Science 299, 1214–1217.
Hornafius, J.S., Quigley, D., Luyendyk, B.P., 1999. The world's most
spectacular marine hydrocarbon seeps (Coal Oil Point, Santa Barbara
Channel, California): quantification of emissions. J. Geophys. Res. 104,
20703–20711.
Hovland, M., Judd, A.G., 1988. Seabed Pockmarks and Seepages: Impact on
Geology, Biology, and theMarine Environment. Graham& Trotman, London.
Hunt, J.M., 1996. Petroleum Geochemistry and Geology. W.H. Freeman and
Co., New York. 743 pp.
Huseynov, D.A., Guliyev, I.S., 2004. Mud volcanic natural phenomena in the
South Caspian Basin: geology, fluid dynamics and environmental impact.
Environ. Geol. 46, 1012–1023.
Intergovernmental Panel on Climate Change, 2001. In: Houghton, J.T., Ding, Y.,
Griggs, D.J., Noguer, M., van der Linden, P.J., Dai, X., Maskell, K.,
Johnson, C.A. (Eds.), Climate Change 2001: The Scientific Basis.
Cambridge Univ. Press, Cambridge, UK. 881 pp.
Jones, V.T., Drozd, R.J., 1983. Predictions of oil or gas potential by near-surface
geochemistry. AAPG Bull. 67, 932–952.
Judd, A.G., Charlier, R.H., Lacroix, A., Lambert, G., Rouland, C., 1993. Minor
sources of methane. In: Khalil, M.A.K. (Ed.), Atmospheric Methane: Sources, Sinks and Role in Global Change. Springer-Verlag, Berlin
Heidelberg, pp. 432–456.
Judd, A.G., Hovland, M., Dimitrov, L.I., Garcia Gil, S., Jukes, V., 2002. The
geological methane budget at Continental Margins and its influence on
climate change. Geofluids 2, 109–126.
Kennett, J.P., Cannariato, K.G., Hendy, I.L., Behl, R.J., 2003. Methane hydrates
in Quaternary climate change. The Clathrate Gun Hypothesis. American
Geophysical Union, Washington, DC, p. 216.
Klusman, R.W., Jakel, M.E., LeRoy, M.P., 1998. Does microseepage of methane
and light hydrocarbons contribute to the atmospheric budget of methane and
to global climate change? Assoc. Petrol. Geochem. Explor. Bull. 11, 1–55.
Klusman, R.W., Leopold, M.E., LeRoy, M.P., 2000. Seasonal variation in
methane fluxes from sedimentary basins to the atmosphere: results from
chamber measurements and modeling of transport from deep sources. J.
Geophys. Res. 105D, 24,661–24,670.
Kvenvolden, K.A., 1988. Methane hydrates—a major reservoir of caron in the
shallow geosphere? Chem. Geol. 71, 41–51.
Kvenvolden, K.A., Rogers, B.W., 2005. Gaia's breath — global methane
exhalations. Mar. Petrol. Geol. 22, 579–590.
Kvenvolden, K.A., Lorenson, T.D., Reeburgh, W., 2001. Attention turns to
naturally occurring methane seepage. EOS 82, 457.
Lacroix, A.V., 1993. Unaccounted-for sources of fossil and isotopically enriched
methane and their contribution to the emissions inventory: a review and
synthesis. Chemosphere 26, 507–557.
Lavrushin, V.Y., Polyak, B.G., Prasolov, R.M., Kamenskii, I.L., 1996. Sources
of material in mud volcano products (based on isotopic, hydrochmical and
geological data). Lithos Miner. Res. 31, 557–578.
Leifer, I., Patro, R.K., 2002. The bubble mechanism for methane transport from
the shallow sea bed to the surface: a review and sensitivity study. Cont. Shelf
Res. 22 (16), 2409–2428.
Lelieveld, J., Crutzen, P.J., Dentener, F.J., 1998. Changing concentration,
lifetime and climate forcing of atmospheric methane. Tellus 50B, 128–150.
Link, W.K., 1952. Significance of oil and gas seeps in world oil exploration.
AAPG Bull. 36, 1505–1540.
Luyendyk, B., Kennett, J., Clark, J.F., 2005. Hypothesis for increased
atmospheric methane input from hydrocarbon seeps on exposed continental
shelves during glacial low sea level. Mar. Petrol. Geol. 22, 591–596.
Macgregor, D.S., 1993. Relationships between seepage, tectonics and subsurface
petroleum reserves. Mar. Pet. Geol. 10, 606–619.
Maslin, M.A., Thomas, E., 2003. Balancing the deglacial global carbon budget;
the hydrate factor. Quat. Sci. Rev. 22, 1729–1736.
Milkov, A.V., 2000. Worldwide distribution of submarine mud volcanoes and
associated gas hydrates. Mar. Geol. 167, 29–42.
Milkov, A.V., 2004. Global estimates of hydrate-bound gas in marine sediments:
How much is really out there? Earth-Sci. Rev. 66, 183–197.
Milkov, A.V., 2005. Molecular and stable isotope compositions of natural gas
hydrates: A revised global dataset and basic interpretations in the context of
geological settings. Org. Geochem. 36, 681–702.
Milkov, A.V., Sassen, R., 2002. Economic geology of offshore gas hydrate
accumulations and provinces. Mar. Pet. Geol. 19, 1–11.
Milkov, A.V., Sassen, R., 2003. Two-dimensional modeling of gas hydrate
decomposition in the northwestern Gulf of Mexico: significance to global
change assessment. Glob. Planet. Change 36, 31–46.
Milkov, A.V., Claypool, G.E., Lee, Y.-J., Dickens, G.R., Xu, W., Borowski, W.
S., ODP Leg 204 Scientific Party, 2003a. In situ methane concentrations at
Hydrate Ridge offshore Oregon: new constraints on the global gas hydrate
inventory from an active margin. Geology 31, 833–836.
Milkov, A.V., Sassen, R., Apanasovich, T.V., Dadashev, F.G., 2003b. Global gas
flux from mud volcanoes: a significant source of fossil methane in the
atmosphere and the ocean. Geophys. Res. Lett. 30 (2), 1037. doi:10.1029/
2002GL016358.
Milkov, A.V., Vogt, P.R., Crane, K., Lein, A.Yu., Sassen, R., Cherkashev, G.A.,
2004. Geological, geochemical, and microbial processes at the hydratebearing
Håkon Mosby mud volcano: a review. Chem. Geol. 205, 347–366.
Morner, N.A., 1978. Faulting, fracturing and seismicity as functions of glacioisostasy
in Fennoscandia. Geology 6, 41–45.
Morner, N.A., Etiope, G., 2002. Carbon degassing from the lithosphere. Glob.
Planet. Change 33 (1–2), 185–203.
Nisbet, E.G., 2002. Have sudden large releases of methane from geological
reservoirs occurred since the Last Glacial Maximum, and could such
releases occur again? Philos. Trans. R. Soc. Lond. 360, 581–607.
Pentecost, A., 1995. The Quaternary travertine deposits of Europe and Asia
Minor. Quat. Sci. Rev. 14, 1005–1028.
Petit, J.R., Jouzel, J., Raynaud, D., Barkov, N.I., Barnola, J.M., Basile, I.,
Bender, M., Chappellaz, J., Davis, M., Delaygue, G., Delmotte, M.,
Kotlyakov, V.M., Legrand, M., Lipenkov, V.Y., Lorius, C., Pepin, L., Ritz,
C., Saltzman, E., Stievenard, M., 1999. Climate and atmospheric history of
the past 420,000 years from the Vostok ice core, Antarctica. Nature 399,
429–436.
Planke, S., Svensen, H., Hovland, M., Banks, D.A., Jamtveit, B., 2003. Mud and
fluid migration in active mud volcanoes in Azerbaijan. Geo Mar. Lett. 23,
258–268.
Quay, P., Stutsman, J., Wilbur, D., Snover, A., Dlugokencky, E., Brown, T.,
1999. The isotopic composition of atmospheric methane. Glob. Biogeochem.
Cycles 13, 445–461.
Quigley, D.C., Hornafius, J.S., Luyendyk, B.P., Francis, R.D., Clark, J.,
Washburn, L., 1999. Decrease in natural marine hydrocarbon seepage near
Coal Oil Point, California, associated with offshore oil production. Geology
27, 1047–1050.
Revil, A., 2002. Genesis of mud volcanoes in sedimentary basins: a solitary wavebased
mechanism. Geophys. Res. Lett. 29, 12. doi:10.1029/2001GL014465.
Schaefer, H., Whiticar, M.J., Brook, E.J., Petrenko, V.V., Ferretti, D.F.,
Severinghaus, J.P., 2006. Ice record of d13C for atmospheric CH4 across
the Younger Dryas–Preboreal transition. Science 313, 1109–1112.
Sowers, T.A., 2000. The δ13C of atmospheric CH4 over the past 30,000 years as
recorded in the Taylor Dome ice core. Eos Trans. AGU 81 (48) (Fall Meet.
Suppl., Abstract A62A-04, 2000).
Sowers, T., 2006. Late Quaternary atmospheric CH4 isotope record suggests
marine clathrates are stable. Science 311, 838–840.
Stewart, I., Sauber, J., Rose, J., 2000. Glacio-seismotectonics: ice sheets, crustal
deformation and seismicity. Quat. Sci. Rev. 19, 1367–1389.
Svensen, H., Planke, S., Jamtveit, B., Pedersen, T., 2003. Seep carbonate
formation controlled by hydrothermal vent complexes: a case study from the
Vøring volcanic basin, the Norwegian Sea. Geo Mar. Lett. 23, 351–358.
Svensen, H., Planke, S., Malthe-Sørenssen, A., Jamtveit, B., Myklebust, R.,
Eidem, T., Rey, S.S., 2004. Release of methane from a volcanic basin as a
mechanism for initial Eocene global warming. Nature 429, 542–545.
Taviani, M., 2001. Fluid venting and associated processes. In: Vai, G.B.,
Martini, I.P. (Eds.), Anatomy of an Orogen: The Apennines and Adjacent
Mediterranean Basins. KluwerAcademic, Dordrecht, pp. 351–366.
Terzi, C., Aharon, P., Ricci Lucchi, F., Vai, G.B., 1994. Petrography and stable
isotope aspects of cold-vent activity imprinted on Miocene-age ‘calcari a
Lucina’ from Tuscana and Romagna Apennines, Italy. Geo Mar. Lett. 14,
177–184.
Thompson, A.M., Chappellaz, J.A., Fung, I.Y., Kucsera, T.L., 1993. The
atmospheric CH4 increase since the Last Glacial Maximum (2). Interactions
with oxidants. Tellus 45B, 242–257.
Torgersen, T., O'Donnell, J., 1991. The degassing flux from the solid earth:
release by fracturing. Geophys. Res. Lett. 18 (5), 951–954.
Torres, M.E., Mix, A.C., Kinports, K., Haley, B., Klinkhammer, G.P.,
McManus, J., de Angelis, M.A., 2003. Is methane venting at the seafloor
recorded by d13C of benthic foraminifera shells? Paleoceanography 18 (3),
1062. doi:10.1029/2002PA000824.
Tyler, S.C.,Ajie,H.O.,Gupta,M.L., Cicerone,R.J.,Blacke,D.R.,Dlugokencky, E.
J., 1999. Carbon isotopic composition of atmospheric methane: a comparison
of surface level and upper tropospheric air. J. Geophys. Res. 104,
13,895–13,910.
Valentine, D.L., Blanton, D.C., Reeburgh, W.S., Kastner, M., 2001. Water
column methane oxidation adjacent to an area of active hydrate dissociation,
Eel river Basin. Geochim. Cosmochim. Acta 65, 2633–2640.
Wu, P., Johnston, P., Lambeck, K., 1999. Postglacial rebound and fault
instability in Fennoscandia. Geophys. J. Int. 139, 657–670.
Wuebbles, D.J., Hayhoe, K., 2002. Atmospheric methane and global change.
Earth-Sci. Rev. 57, 177–210.
Yusifov, M., Rabinowitz, P.D., 2004. Classification of mud volcanoes in the
South Caspian Basin, offshore Azerbaijan. Mar. Pet. Geol. 21, 965–975.
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