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Methane chimney

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Illustration showing methane chimney from sea floor to surface.

A methane chimney or gas chimney is a rising column of natural gas, mainly methane, within a water or sediment column. The contrast in physical properties between the gas phase and the surrounding water makes such chimneys visible in oceanographic and geophysical data. In some cases, gas bubbles released at the seafloor may dissolve before they reach the ocean surface, but the increased hydrocarbon concentration may still be measured by chemical oceanographic techniques.

Identification

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In some locations along Russia’s northern coast, methane rising from the sea floor to the surface has caused the sea to foam.[1] However, most methane chimneys do not produce such visible signs at the sea surface. Instead, plumes are identified by a combination of chemical and physical oceanographic and geologic data.[2] Plumes of methane bubbles, whether in the water column or subseafloor sediments, have lower density and sound speed than the surrounding water. As such, these plumes can be imaged by a variety of acoustic techniques, including seismic reflection data and conventional fishfinders. Dissolved methane is usually identified through widespread chemical analysis of water samples, including chromatography of gasses extracted from the headspace of seawater samples taken at depth (headspace is the space above a sample in a sealed container, which forms as higher temperature and lower pressure allows gasses to come out of solution). Continuous measurements of methane concentration in seawater can be made by underway ships using cavity ring-down spectroscopy.

Association with climate change

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Large deposits of frozen methane, when thawing, release gas into the environment.[3] In cases of sub-sea permafrost, the methane gas may be dissolved in the seawater before reaching the surface; however, in a number of sites around the world, these methane chimneys release the gas directly into the atmosphere, contributing to global warming.[4] Research teams in the Arctic measured concentrations of methane to be the highest ever recorded in the summertime.[5] The thawing underwater permafrost is affecting methane release in two ways: thawing organic matter trapped in the permafrost releases methane and carbon dioxide as it decomposes, and methane in gas or solid form beneath the thawing permafrost seeps up through the now-soft soil and escapes into the atmosphere.[6] In part of the International Siberian Shelf Study, which looked at arctic methane emissions, scientists discovered that methane concentrations released from subsea chimneys and seeps were often 100 times higher than background levels, and methane gas has 20 times the heat-trapping capabilities as carbon dioxide.[7]

Marine life

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Methane chimneys play a major role in marine life, creating chemical deposits that are habitat to a plethora of life.[8] These highly-productive ecosystems occur in a wide range of marine geological settings across the world.[9] Chimneys teem with organisms that feed on the methane and sulfide that are released from the chimneys.[10] Life surrounding the marine methane chimneys consumes 90% of methane released, preventing it from entering the atmosphere.[11] Microbes around methane chimneys form the basis for the entire food web; these microbes are chemolithotrophs, and thus do not require sunlight or oxygen to survive.[12] Marine methane chimneys produce minerals that fertilize the ocean, creating optimal spawning habitats for deep-sea sharks and other fish.[13][14] They are also host to deep-sea crabs, shrimp, mussels, clams, and more shellfish. The expanse of life and ecosystems that these vents provide is still largely unexplored.[15]

Petroleum provinces

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In hydrocarbon exploration, gas chimneys revealed on seismic reflection data are indicators of active gas migration[16] and a working petroleum system.

Trees as methane chimneys

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Trees in swampy, low-lying areas can conduct methane produced in soils up through their stems and out their leaves. Other plants in bogs and marshes also act in this way. In the Amazon Rainforest, recent studies have named trees a "massive chimney for pumping out methane".[17] Findings estimated that the Amazon Rainforest emits around 40 million tons of methane per year, as much as the entire arctic permafrost systems.[18] When large portions of the Amazon Basin flood, they create ideal conditions for high-level methane production.[19] The methane flux is a result of abiotic factors such as soil moisture and climate. As seen in the figure 2 of the Quercus cerris tree in Hungary, a cool climate plant that demands moderate soil moisture can be observed to contain flammable concentrations of methane emitted from the stem contraption.[20][21]

Trees are not the only plants that act as methane chimneys; however, studies have shown that species with greater root volume and biomass tend to exhibit a stronger chimney effect, and methane emissions in plant species are increased by raising the water table.[22]

Known sites

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See also

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References

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  1. ^ "Yale Environment 360: Numerous Methane 'Chimneys'Discovered by Vessel in Russian Arctic". E360.yale.edu. 2008-09-23. Archived from the original on 2010-06-14. Retrieved 2010-07-30.
  2. ^ "Climate-Hydrate Interactions". usgs.gov. United States Geological Survey. Retrieved August 31, 2016.
  3. ^ Connor, S. (23 September 2008). "Exclusive: The methane time bomb". The Independent. London. Retrieved 3 April 2010.
  4. ^ "Oh Floe! Melting Ice Releases Millions of Tons of Methane Gas". Tressugar.com. 2008-09-24. Retrieved 2010-07-30.
  5. ^ "Scientists Find Increased Methane Levels In Arctic Ocean". ScienceDaily. Retrieved 2021-03-21.
  6. ^ "Scientists Find Increased Methane Levels In Arctic Ocean". ScienceDaily. Retrieved 2021-03-21.
  7. ^ "A Ticking Time Bomb in the Arctic?". National Wildlife Federation. Retrieved 2021-03-21.
  8. ^ "Hydrothermal vents, methane seeps play enormous role in marine life, global climate". phys.org. Retrieved 2021-03-17.
  9. ^ Levin, Lisa A.; Baco, Amy R.; Bowden, David A.; Colaco, Ana; Cordes, Erik E.; Cunha, Marina R.; Demopoulos, Amanda W. J.; Gobin, Judith; Grupe, Benjamin M.; Le, Jennifer; Metaxas, Anna (2016). "Hydrothermal Vents and Methane Seeps: Rethinking the Sphere of Influence". Frontiers in Marine Science. 3. doi:10.3389/fmars.2016.00072. ISSN 2296-7745.
  10. ^ "Hydrothermal vents, methane seeps play enormous role in marine life, global climate". phys.org. Retrieved 2021-03-17.
  11. ^ "Hydrothermal vents, methane seeps play enormous role in marine life, global climate". phys.org. Retrieved 2021-03-17.
  12. ^ Guy, Allison. "Fueled by Methane Gas, Bizarre Animals Flourish at Deep Sea "Jacuzzis"". Oceana. Retrieved 2021-03-21.
  13. ^ "Hydrothermal vents, methane seeps play enormous role in marine life, global climate". phys.org. Retrieved 2021-03-17.
  14. ^ Guy, Allison. "Fueled by Methane Gas, Bizarre Animals Flourish at Deep Sea "Jacuzzis"". Oceana. Retrieved 2021-03-21.
  15. ^ "Hydrothermal vents, methane seeps play enormous role in marine life, global climate". phys.org. Retrieved 2021-03-17.
  16. ^ Schroot, B.M.; Schüttenhelm R.T.E. (2003). "Expressions of shallow gas in the Netherlands North Sea". Netherlands Journal of Geosciences. 82 (1): 91–105. Bibcode:2003NJGeo..82...91S. doi:10.1017/S0016774600022812.
  17. ^ "Scientists Zero in on Trees as a Surprisingly Large Source of Methane". Yale E360. Retrieved 2021-03-22.
  18. ^ "Scientists Zero in on Trees as a Surprisingly Large Source of Methane". Yale E360. Retrieved 2021-03-22.
  19. ^ "Amazon floodplain trees emit as much methane as all Earth's oceans combined". ScienceDaily. Retrieved 2021-03-22.
  20. ^ Covey, Kristofer R.; Megonigal, J. Patrick (April 2019). "Methane production and emissions in trees and forests". New Phytologist. 222 (1): 35–51. doi:10.1111/nph.15624. ISSN 0028-646X. PMID 30521089. S2CID 54552281.
  21. ^ "Quercus cerris - EUFORGEN European forest genetic resources programme". www.euforgen.org. Retrieved 2023-10-22.
  22. ^ Bhullar, Gurbir S; Iravani, Majid; Edwards, Peter J; Olde Venterink, Harry (2013-09-08). "Methane transport and emissions from soil as affected by water table and vascular plants". BMC Ecology. 13 (1): 32. Bibcode:2013BMCE...13...32B. doi:10.1186/1472-6785-13-32. ISSN 1472-6785. PMC 3847209. PMID 24010540.
  23. ^ "Quantifying the Methane Content of Natural Gas and Gas Hydrate Accumulations in the Deep-Water Basins of the Bering Sea, by Ginger A. Barth, David W. Scholl, and Jonathan R. Childs; #90035 (2004)". Searchanddiscovery.net. Retrieved 2010-07-30.
  24. ^ James Randerson, science correspondent (2008-09-23). "Methane release off Siberian coast prompts concern over runaway climate change | Environment | guardian.co.uk". London: Guardian. Retrieved 2010-07-30. {{cite news}}: |author= has generic name (help)
  25. ^ Magalhães et al., (2012) Formation processes of methane-derived authigenic carbonates from theGulf of Cadiz. Sedimentary Geology, 243-244, pp.155-168.
  26. ^ Snyder, Glen T.; Sano, Yuji; Takahata, Naoto; Matsumoto, Ryo; Kakizaki, Yoshihiro; Tomaru, Hitoshi (2020-03-05). "Magmatic fluids play a role in the development of active gas chimneys and massive gas hydrates in the Japan Sea". Chemical Geology. 535: 119462. Bibcode:2020ChGeo.53519462S. doi:10.1016/j.chemgeo.2020.119462. ISSN 0009-2541.
  27. ^ Aoyama, C.; Matsumoto, R.; Okuda, Y.; Ishida, Y.; Hiruta, A.; Sunamura, M.; Numamani, H.; Tomaru, H.; Snyder, G.; Komatsubara, J.; Takeuchi, R. (November 2004). "Acoustical survey of methane plumes using the quantitative echo sounder in the eastern margin of the sea of Japan". Oceans '04 MTS/IEEE Techno-Ocean '04 (IEEE Cat. No.04CH37600). AGU Meeting Abstracts. Vol. 2. pp. 1004–1009. Bibcode:2004AGUFMPP11B0576A. doi:10.1109/OCEANS.2004.1405646. ISBN 0-7803-8669-8. S2CID 9512671.
  28. ^ Matsumoto, R.; Tomaru, H.; Takeuchi, L.; Hiruta, A.; Ishizaki, O.; Aoyama, C.; Machiyama, H.; Goto, T. (December 2007). "Types and Evolution of Gas Hydrate System along the Tectonically Active Zones of the Western Pacific: Nankai Trough vs. Eastern Margin of Japan Sea". AGUFM. 2007: OS12A–01. Bibcode:2007AGUFMOS12A..01M.
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