Reappraisal of the fossil methane budget and related emission from geologic sources
Author(s)
Language
English
Obiettivo Specifico
3.8. Geofisica per l'ambiente
Status
Published
JCR Journal
JCR Journal
Peer review journal
Yes
Journal
Issue/vol(year)
/ 35 (2008)
Publisher
AGU
Pages (printed)
L09307
Date Issued
May 2008
Alternative Location
Abstract
Converging evidence from new top-down and bottomup estimates of fossil "radiocarbon-free" methane emissions indicates that natural geologic sources account for a substantial component of the atmospheric methane budget.
Comparing emission estimates based on atmospheric 14CH4 ("radiomethane") with geologic emissions from seepage, including terrestrial macroseeps, microseepage, marine
seeps, and geothermal/volcanic emissions from the Earth’s crust, shows that such "geo-CH4" sources can be conservatively estimated at 53 ± 11 Tg yr 1 globally. This makes geo-CH4 second in importance to wetlands as a natural
methane source. Such a new appraisal can easily be accommodated within the uncertainty of the global methane budget as recently compiled, and recognizes the importance of geophysical out-gassing of methane generated
within the lithosphere. We propose a new coherent contemporary budget in which 30 ± 5% (based on atmospheric radiomethane measurements) of the global source of 582 ± 87 Tg yr 1 has fossil origin, both natural
and anthropogenic.
Comparing emission estimates based on atmospheric 14CH4 ("radiomethane") with geologic emissions from seepage, including terrestrial macroseeps, microseepage, marine
seeps, and geothermal/volcanic emissions from the Earth’s crust, shows that such "geo-CH4" sources can be conservatively estimated at 53 ± 11 Tg yr 1 globally. This makes geo-CH4 second in importance to wetlands as a natural
methane source. Such a new appraisal can easily be accommodated within the uncertainty of the global methane budget as recently compiled, and recognizes the importance of geophysical out-gassing of methane generated
within the lithosphere. We propose a new coherent contemporary budget in which 30 ± 5% (based on atmospheric radiomethane measurements) of the global source of 582 ± 87 Tg yr 1 has fossil origin, both natural
and anthropogenic.
References
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Etiope, G. (2004), GEM—Geologic emissions of methane, the missing
source in the atmospheric methane budget, Atmos. Environ., 38, 3099–
3100.
Etiope, G. (2008), Natural emissions of methane from geological sources in
Europe, Atmos. Environ., doi:10.1016/j.atmosenv.2008.03.014, in press.
Etiope, G., and R. W. Klusman (2002), Geologic emissions of methane to
the atmosphere, Chemosphere, 49, 777– 789.
Etiope, G., and R. W. Klusman (2008), Microseepage in drylands: Flux and
implications in the global atmospheric source/sink budget of methane,
Global Planet. Change, in press.
Etiope, G., and A. V. Milkov (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., A. Feyzullayev, C. L. Baciu, and A. V. Milkov (2004), Methane
emission from mud volcanoes in eastern Azerbaijan, Geology, 32, 465–
468.
Etiope, G., G. Papatheodorou, D. Christodoulou, G. Ferentinos, E. Sokos,
and P. Favali (2006), Methane and hydrogen sulfide seepage in the NW
Peloponnesus petroliferous basin (Greece): Origin and geohazard, AAPG
Bull., 90, 701– 713.
Etiope, G., G. Martinelli, A. Caracausi, and F. Italiano (2007a), Methane
seeps and mud volcanoes in Italy: Gas origin, fractionation and emission
to the atmosphere, Geophys. Res. Lett., 34, L14303, doi:10.1029/
2007GL030341.
Etiope, G., T. Fridriksson, F. Italiano, W. Winiwarter, and J. Theloke
(2007b), Natural emissions of methane from geothermal and volcanic
sources in Europe, J. Volcanol. Geotherm. Res., 165, 76 – 86,
doi:10.1016/j.jvolgeores.2007.04.014.
Etiope, G., A. V. Milkov, and E. Derbyshire (2008), Did geologic emissions
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Emission Inventory Guidebook, 4th ed., Copenhagen. (Available
at http://reports.eea.eu.int/EMEPCORINAIR4/en.)
Hong, W. L., and T .F. Yang (2007), Methane flux from accretionary prism
through mud volcano area in Taiwan: From present to the past, paper
presented at 9th International Conference on Gas Geochemistry, Natl.
Taiwan Univ., Taipei, Taiwan.
Hornafius, J. S., D. Quigley, and B. P. Luyendyk (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.
Houweling, S., F. Dentener, and J. Lelieveld (2000), Simulation of preindustrial
methane to constrain the global source strength of natural wetlands,
J. Geophys. Res., 105, 17243–17255.
Judd, A. G. (2004), Natural seabed seeps as sources of atmospheric
methane, Environ. Geol., 46, 988– 996.
Klusman, R. W., M. E. Jakel, and M. P. LeRoy (1998), Does microseepage
of methane and light hydrocarbons contribute to the atmospheric budget
of methane and to global climate change?, Assoc. Pet. Geochem. Explor.
Bull., 11, 1– 55.
Kvenvolden, K. A., and B. W. Rogers (2005), Gaia’s breath—Global
methane exhalations, Mar. Pet. Geol., 22, 579– 590.
Kvenvolden, K. A., T. D. Lorenson, and W. Reeburgh (2001), Attention
turns to naturally occurring methane seepage, Eos Trans. AGU, 82, 457,
2001.
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enriched methane and their contribution to the emissions inventory:
A review and synthesis, Chemosphere, 26, 507– 557.
Lassey, K. R., D. C. Lowe, and A. M. Smith (2007), The atmospheric
cycling of radiomethane and the ‘‘fossil fraction’’ of the methane source,
Atmos. Chem. Phys., 7, 2141– 2149.
Lelieveld, J., P. J. Crutzen, and F. J. Dentener (1998), Changing concentration,
lifetime and climate forcing of atmospheric methane, Tellus, Ser. B,
50, 128– 150.
Mellors, R., D. Kilb, A. Aliyev, A. Gasanov, and G. Yetirmishli (2007),
Correlations between earthquakes and large mud volcano eruptions,
J. Geophys. Res., 112, B04304, doi:10.1029/2006JB004489.
Milkov, A. V., R. Sassen, T. V. Apanasovich, and F. G. Dadashev (2003),
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.
Mo¨rner, N.-A., and G. Etiope (2002), Carbon degassing from the lithosphere,
Global Planet. Change, 33, 185– 203.
Prather, M., et al. (2001) Atmospheric chemistry and greenhouse gases, in
Climate Change 2001: The Scientific Basis. Contribution of Working
Group I to the Third Assessment Report of the Intergovernmental Panel
on Climate Change, edited by J. T. Houghton et al., pp. 239–287, Cambridge
Univ. Press, Cambridge, U.K.
Quay, P., J. Stutsman, D. Wilbur, A. Snover, E. Dlugokencky, and T. Brown
(1999), The isotopic composition of atmospheric methane, Global Biogeochem.
Cycles, 13, 445– 461.
Ryan, S., E. J. Dlugokencky, P. P. Tans, and M. E. Trudeau (2006), Mauna
Loa volcano is not a methane source: Implications for Mars, Geophys.
Res. Lett., 33, L12301, doi:10.1029/2006GL026223.
Schimel, D., et al. (1996), Radiative forcing of climate change, in Climate
Change 1995: The Science of Climate Change, edited by J. T. Houghton
et al., pp. 65– 131, Cambridge Univ. Press, Cambridge, U.K.
migration, in Petroleum Migration, edited by W. A. England and A. J.
Fleet, Geol. Soc. Spec. Publ., 59, 265– 271.
Denman, K. L., et al. (2007), Couplings between changes in the climate
system and biogeochemistry, in Climate Change 2007: The Physical
Science Basis. Contribution of Working Group I to the Fourth Assessment
Report of the Intergovernmental Panel on Climate Change, edited by
S. Solomon et al., chap. 7, pp. 499 – 587, Cambridge Univ. Press,
Cambridge, U.K.
Dimitrov, L. (2002), Mud volcanoes—The most important pathway for
degassing deeply buried sediments, Earth Sci. Rev., 59, 49–76.
Etiope, G. (2004), GEM—Geologic emissions of methane, the missing
source in the atmospheric methane budget, Atmos. Environ., 38, 3099–
3100.
Etiope, G. (2008), Natural emissions of methane from geological sources in
Europe, Atmos. Environ., doi:10.1016/j.atmosenv.2008.03.014, in press.
Etiope, G., and R. W. Klusman (2002), Geologic emissions of methane to
the atmosphere, Chemosphere, 49, 777– 789.
Etiope, G., and R. W. Klusman (2008), Microseepage in drylands: Flux and
implications in the global atmospheric source/sink budget of methane,
Global Planet. Change, in press.
Etiope, G., and A. V. Milkov (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., A. Feyzullayev, C. L. Baciu, and A. V. Milkov (2004), Methane
emission from mud volcanoes in eastern Azerbaijan, Geology, 32, 465–
468.
Etiope, G., G. Papatheodorou, D. Christodoulou, G. Ferentinos, E. Sokos,
and P. Favali (2006), Methane and hydrogen sulfide seepage in the NW
Peloponnesus petroliferous basin (Greece): Origin and geohazard, AAPG
Bull., 90, 701– 713.
Etiope, G., G. Martinelli, A. Caracausi, and F. Italiano (2007a), Methane
seeps and mud volcanoes in Italy: Gas origin, fractionation and emission
to the atmosphere, Geophys. Res. Lett., 34, L14303, doi:10.1029/
2007GL030341.
Etiope, G., T. Fridriksson, F. Italiano, W. Winiwarter, and J. Theloke
(2007b), Natural emissions of methane from geothermal and volcanic
sources in Europe, J. Volcanol. Geotherm. Res., 165, 76 – 86,
doi:10.1016/j.jvolgeores.2007.04.014.
Etiope, G., A. V. Milkov, and E. Derbyshire (2008), Did geologic emissions
of methane play any role in Quaternary climate change?, Global Planet.
Change, 61, 79–88, doi:10.1016/j.gloplacha.2007.08.008.
European Environment Agency (2004), Joint EMEP/CORINAIR Atmospheric
Emission Inventory Guidebook, 4th ed., Copenhagen. (Available
at http://reports.eea.eu.int/EMEPCORINAIR4/en.)
Hong, W. L., and T .F. Yang (2007), Methane flux from accretionary prism
through mud volcano area in Taiwan: From present to the past, paper
presented at 9th International Conference on Gas Geochemistry, Natl.
Taiwan Univ., Taipei, Taiwan.
Hornafius, J. S., D. Quigley, and B. P. Luyendyk (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.
Houweling, S., F. Dentener, and J. Lelieveld (2000), Simulation of preindustrial
methane to constrain the global source strength of natural wetlands,
J. Geophys. Res., 105, 17243–17255.
Judd, A. G. (2004), Natural seabed seeps as sources of atmospheric
methane, Environ. Geol., 46, 988– 996.
Klusman, R. W., M. E. Jakel, and M. P. LeRoy (1998), Does microseepage
of methane and light hydrocarbons contribute to the atmospheric budget
of methane and to global climate change?, Assoc. Pet. Geochem. Explor.
Bull., 11, 1– 55.
Kvenvolden, K. A., and B. W. Rogers (2005), Gaia’s breath—Global
methane exhalations, Mar. Pet. Geol., 22, 579– 590.
Kvenvolden, K. A., T. D. Lorenson, and W. Reeburgh (2001), Attention
turns to naturally occurring methane seepage, Eos Trans. AGU, 82, 457,
2001.
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.
Lassey, K. R., D. C. Lowe, and A. M. Smith (2007), The atmospheric
cycling of radiomethane and the ‘‘fossil fraction’’ of the methane source,
Atmos. Chem. Phys., 7, 2141– 2149.
Lelieveld, J., P. J. Crutzen, and F. J. Dentener (1998), Changing concentration,
lifetime and climate forcing of atmospheric methane, Tellus, Ser. B,
50, 128– 150.
Mellors, R., D. Kilb, A. Aliyev, A. Gasanov, and G. Yetirmishli (2007),
Correlations between earthquakes and large mud volcano eruptions,
J. Geophys. Res., 112, B04304, doi:10.1029/2006JB004489.
Milkov, A. V., R. Sassen, T. V. Apanasovich, and F. G. Dadashev (2003),
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.
Mo¨rner, N.-A., and G. Etiope (2002), Carbon degassing from the lithosphere,
Global Planet. Change, 33, 185– 203.
Prather, M., et al. (2001) Atmospheric chemistry and greenhouse gases, in
Climate Change 2001: The Scientific Basis. Contribution of Working
Group I to the Third Assessment Report of the Intergovernmental Panel
on Climate Change, edited by J. T. Houghton et al., pp. 239–287, Cambridge
Univ. Press, Cambridge, U.K.
Quay, P., J. Stutsman, D. Wilbur, A. Snover, E. Dlugokencky, and T. Brown
(1999), The isotopic composition of atmospheric methane, Global Biogeochem.
Cycles, 13, 445– 461.
Ryan, S., E. J. Dlugokencky, P. P. Tans, and M. E. Trudeau (2006), Mauna
Loa volcano is not a methane source: Implications for Mars, Geophys.
Res. Lett., 33, L12301, doi:10.1029/2006GL026223.
Schimel, D., et al. (1996), Radiative forcing of climate change, in Climate
Change 1995: The Science of Climate Change, edited by J. T. Houghton
et al., pp. 65– 131, Cambridge Univ. Press, Cambridge, U.K.
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