User:BaileyLin/Marsh gas

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Bubbles of methane, created by methanogens, that are present in the marsh- more commonly known as marsh gas.

Marsh gas, also known as swamp gas or bog gas, is a mixture of methane, hydrogen sulfide, carbon dioxide, and trace phosphine produced naturally within some geographical marshes, swamps, and bogs.

The surface of marshes, swamps, and bogs is initially porous vegetation that rots to form a crust that prevents oxygen from reaching the organic material trapped below. This is the condition that allows anaerobic digestion and fermentation of any plant or animal matter, which incidentally also produces methane.

The trapped methane is able to escape through any of these three main pathways: by the diffusion of methane molecules across an air–water interface, by bubbling out of water in a process known as ebullition, or through plant-mediated transport ^[1].

Methane Formation

Methane is the primary gas that makes up the product colloquially known as "marsh gas". Much of the biogenic methane produced in nature is derived from either acetate cleavage or by the hydrogen reduction of carbon dioxide. Methane can also be produced by methanogens, prokaryotic microorganisms that produce methane under hypoxic conditions, in a process known as methanogenesis. There are two known species of methanogens, Methanosarcina barkeri and Methanococcus mazei, that are found in marsh environments. They are both known to stimulate methane production in aquatic muds and use methanol and trimethylamine as substrates for methane production ^[2].

Escape Routes

 

Methane gas using the three escape routes: ebullition (bubbling), plant-mediated transport, and diffusion.

Global wetlands are one of the largest sources of atmospheric methane. This methane, which is produced by the decomposition of organic matter in an anoxic environment, escapes through either diffusion, a process that occurs mostly at night, ebullition, or plant-mediated transportation.

The diffusive process is controlled by the passage of gas across the air–water interface ^[1]. The diffusion can be accelerated and intensified by upwelling motions, such as the motion from turbulent eddies, and cooling processes. At night, heat is emitted from the water surface by radiation. The colder surface water sinks, pushing the warmer surface water out and forming eddies. These eddies circulate the dissolved methane throughout the water column and increase the methane flux to the atmosphere. This process is called hydrodynamic transport ^[3], and it accounts for more than half of nighttime methane fluxes as well as 32% of annual methane emissions from wetland environments.

Ebullition, also known as bubbling, is a type of one-way transport of gases from nutrient rich sediments, to the water column, and then to the atmosphere. It is a major mechanism for gas exchange in freshwater and coastal marine ecosystems and is known to peak during the daytime and at warm temperatures ^[3]. It has been reported that ebullition is responsible for 45% of the annual methane flux for fresh water marshes, and that it is more important in the summer months during the daytime and can also be triggered by increased wind.

One of the most common species of grass in marsh environments is Spartina. These spartina and other common marsh grasses use a gas transport system found in the stems and roots of the plants. The gas transport system works by gaseous diffusion that occurs through the leaf blades and then moves down into the furthest tips of the plant roots. This transport system is sufficient to supply all of the aerobic respiratory needs of the grass roots and also helps to aerate the surrounding mud ^[4].

Human Impact

Over the past century, more than 50% of the original tidal salt marsh habitats in the U.S. have been lost. The majority of this loss can be directly accounted for by human activity. Direct human impacts that negatively impact salt marshes include: dredging, spoil dumping, grid ditching, canal cutting, leveeing, and salt hay farming. Indirect impacts, such as land reclamation projects and dam construction, which usually occur over a longer period of time than the direct impacts, can lead to even more damages that affect tidal flooding at the marsh surface, cause changes to wetland drainage, shoreline retreat, and reduce vertical marsh accretion rates. Changes in eustatic sea level due to the increase of anthropogenic greenhouse gases and sulfate aerosols in the atmosphere also pose a long-term threat to the stability of various salt marsh habitats across the coastal US ^[5].

See also

• Landfill gas, produced incidentally where municipal solid waste is abandoned.
• Firedamp, produced naturally in coal mines
• Will-o'-the-wisp, mysterious lights that may be ignited methane
• Wetland methane emissions
• Greenhouse gas
• Anoxic waters
• Phosphine ^[6]
• Hydric soil

References

1. Anthony, Katey Walter; MacIntyre, Sally (2016). "Nocturnal escape route for marsh gas". Nature. 535 (7612): 363–365. doi:10.1038/535363a. ISSN 1476-4687.
2. Oremland, Ronald S.; Marsh, Lorraine M.; Polcin, Sandra (1982-03). "Methane production and simultaneous sulphate reduction in anoxic, salt marsh sediments". Nature. 296 (5853): 143–145. doi:10.1038/296143a0. ISSN 1476-4687. {{cite journal}}: Check date values in: |date= (help)
3. Poindexter, Cristina M.; Baldocchi, Dennis D.; Matthes, Jaclyn Hatala; Knox, Sara Helen; Variano, Evan A. (2016). "The contribution of an overlooked transport process to a wetland's methane emissions". Geophysical Research Letters. 43 (12): 6276–6284. doi:10.1002/2016GL068782. ISSN 1944-8007.
4. TEAL, JOHN M.; KANWISHER, JOHN W. (1966). "Gas Transport in the Marsh Grass,Spartina alterniflora". Journal of Experimental Botany. 17 (2): 355–361. doi:10.1093/jxb/17.2.355. ISSN 0022-0957.
5. Kennish, Michael J. (2001). "Coastal Salt Marsh Systems in the U.S.: A Review of Anthropogenic Impacts". Journal of Coastal Research. 17 (3): 731–748. ISSN 0749-0208.
6. Glindemann, Dietmar; Edwards, Marc; Liu, Ji-ang; Kuschk, Peter (2005). "Phosphine in soils, sludges, biogases and atmospheric implications—a review". Ecological Engineering. 24 (5): 457–463. doi:10.1016/j.ecoleng.2005.01.002. ISSN 0925-8574.