Greenhouse gas emissions from wetlands

See also: Marsh gas
A heat map of the planet showing methane emissions from wetlands from 1980 to 2021

Greenhouse gas emissions from wetlands of concern consist primarily of methane and nitrous oxide emissions. Wetlands are the largest natural source of atmospheric methane in the world, and are therefore a major area of concern with respect to climate change.[1][2][3] Wetlands account for approximately 20–30% of atmospheric methane through emissions from soils and plants, and contribute an approximate average of 161 Tg of methane to the atmosphere per year.[4]

Wetlands are characterized by water-logged soils and distinctive communities of plant and animal species that have adapted to the constant presence of water. This high level of water saturation creates conditions conducive to methane production. Most methanogenesis, or methane production, occurs in oxygen-poor environments. Because the microbes that live in warm, moist environments consume oxygen more rapidly than it can diffuse in from the atmosphere, wetlands are the ideal anaerobic environments for fermentation as well as methanogen activity. However, levels of methanogenesis fluctuates due to the availability of oxygen, soil temperature, and the composition of the soil. A warmer, more anaerobic environment with soil rich in organic matter would allow for more efficient methanogenesis.[5]

Some wetlands are a significant source of methane emissions[6][7] and some are also emitters of nitrous oxide.[8][9] Nitrous oxide is a greenhouse gas with a global warming potential 300 times that of carbon dioxide and is the dominant ozone-depleting substance emitted in the 21st century.[10] Wetlands can also act as a sink for greenhouse gases.[11]

Emissions by type of wetland

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Main article: Wetland § Types

Characteristics of wetland classes can assist to inform on magnitude of methane emissions. However, wetland classes have displayed high variability in methane emissions spatially and temporally.[12] Wetlands are often classified by landscape position, vegetation, and hydrologic regime.[13] Wetland classes include marshes, swamps, bogs, fens, peatlands, muskegs, prairie pothole (landform),[14] and pocosins.

Amounts

Depending on their characteristics, some wetlands are a significant source of methane emissions[7] and some are also emitters of nitrous oxide.[8][9]

Methane

Wetlands account for approximately 20–30% of atmospheric methane through emissions from soils and plants.[15]

Nitrous oxide fluxes

Nitrous oxide is a greenhouse gas with a global warming potential 300 times that of carbon dioxide and is the dominant ozone-depleting substance emitted in the 21st century.[10] Excess nutrients mainly from anthropogenic sources have been shown to significantly increase the N2O fluxes from wetland soils through denitrification and nitrification processes (see table below).[16][8][17] A study in the intertidal region of a New England salt marsh showed that excess levels of nutrients might increase N2O emissions rather than sequester them.[16]

Data on nitrous oxide fluxes from wetlands in the southern hemisphere are lacking, as are ecosystem-based studies including the role of dominant organisms that alter sediment biogeochemistry. Aquatic invertebrates produce ecologically-relevant nitrous oxide emissions due to ingestion of denitrifying bacteria that live within the subtidal sediment and water column[18] and thus may also be influencing nitrous oxide production within some wetlands.

Nitrous oxide fluxes from different wetland soils (table adapted from Moseman-Valtierra (2012)[19] and Chen et al. (2010)[20])
Wetland type Location N2O fluxa

(μmol N2O m−2 h−1)

Reference
Mangrove Shenzhen and Hong Kong 0.14 to 23.83 [20]
Mangrove Muthupet, South India 0.41 to 0.77 [21]
Mangrove Bhitarkanika, East India 0.20 to 4.73 [22]
Mangrove Pichavaram, South India 0.89 to 1.89 [22]
Mangrove Queensland, Australia −0.045 to 0.32 [23]
Mangrove South East Queensland, Australia 0.091 to 1.48 [24]
Mangrove Southwest coast, Puerto Rico 0.12 to 7.8 [25]
Mangrove Isla Magueyes, Puerto Rico 0.05 to 1.4 [25]
Salt marsh Chesapeake Bay, US 0.005 to 0.12 [26]
Salt marsh Maryland, US 0.1 [27]
Salt marsh North East China 0.1 to 0.16 [28]
Salt marsh Biebrza, Poland −0.07 to 0.06 [29]
Salt marsh Netherlands 0.82 to 1.64 [30]
Salt marsh Baltic Sea −0.13 [31]
Salt marsh Massachusetts, US −2.14 to 1.27 [32]

aThe flux rates are shown as hourly rates per unit area. A positive flux implies flux from soil into air; a negative flux implies flux from air into the soil.[33] Negative N2O fluxes are common and are caused by consumption by the soil.[34]

Pathways of methane emission

Wetlands counteract the sinking action that normally occurs with soil because of the high water table. The level of the water table represents the boundary between anaerobic methane production and aerobic methane consumption. When the water table is low, the methane generated within the wetland soil has to come up through the soil and get past a deeper layer of methanotrophic bacteria, thereby reducing emission. Methane transport by vascular plants can bypass this aerobic layer, thus increasing emission.[35][36]

Once produced, methane can reach the atmosphere via three main pathways: molecular diffusion, transport through plant aerenchyma, and ebullition. Primary productivity fuels methane emissions both directly and indirectly because plants not only provide much of the carbon needed for methane producing processes in wetlands but can affect its transport as well.[citation needed]

Fermentation

Fermentation is a process used by certain kinds of microorganisms to break down essential nutrients. In a process called acetoclastic methanogenesis, microorganisms from the classification domain archaea produce methane by fermenting acetate and H2-CO2 into methane and carbon dioxide.

H3C-COOH → CH4 + CO2

Depending on the wetland and type of archaea, hydrogenotrophic methanogenesis, another process that yields methane, can also occur. This process occurs as a result of archaea oxidizing hydrogen with carbon dioxide to yield methane and water.

4H2 + CO2 → CH4 + 2H2O

Diffusion

Diffusion through the profile refers to the movement of methane up through soil and bodies of water to reach the atmosphere. The importance of diffusion as a pathway varies per wetland based on the type of soil and vegetation.[37] For example, in peatlands, the mass amount of dead, but not decaying, organic matter results in relatively slow diffusion of methane through the soil.[38] Additionally, because methane can travel more quickly through soil than water, diffusion plays a much bigger role in wetlands with drier, more loosely compacted soil.

Aerenchyma

plant aerenchyma
Plant-mediated methane flux through plant aerenchyma, shown here, can contribute 30–100% of the total methane flux from wetlands with emergent vegetation.[39]

Plant aerenchyma refers to the vessel-like transport tubes within the tissues of certain kinds of plants. Plants with aerenchyma possess porous tissue that allows for direct travel of gases to and from the plant roots. Methane can travel directly up from the soil into the atmosphere using this transport system.[38] The direct "shunt" created by the aerenchyma allows for methane to bypass oxidation by oxygen that is also transported by the plants to their roots.

Ebullition

Ebullition refers to the sudden release of bubbles of methane into the air. These bubbles occur as a result of methane building up over time in the soil, forming pockets of methane gas. As these pockets of trapped methane grow in size, the level of the soil will slowly rise up as well. This phenomenon continues until so much pressure builds up that the bubble "pops," transporting the methane up through the soil so quickly that it does not have time to be consumed by the methanotrophic organisms in the soil. With this release of gas, the level of soil then falls once more.

Ebullition in wetlands can be recorded by delicate sensors, called piezometers, that can detect the presence of pressure pockets within the soil. Hydraulic heads are also used to detect the subtle rising and falling of the soil as a result of pressure build up and release. Using piezometers and hydraulic heads, a study was done in northern United States peatlands to determine the significance of ebullition as a source of methane. Not only was it determined that ebullition is in fact a significant source of methane emissions in northern United States peatlands, but it was also observed that there was an increase in pressure after significant rainfall, suggesting that rainfall is directly related to methane emissions in wetlands.[40]

Controlling factors

The magnitude of methane emission from a wetland are usually measured using eddy covariance, gradient or chamber flux techniques, and depends upon several factors, including water table, comparative ratios of methanogenic bacteria to methanotrophic bacteria, transport mechanisms, temperature, substrate type, plant life, and climate. These factors work together to effect and control methane flux in wetlands.

Overall the main determinant of net flux of methane into the atmosphere is the ratio of methane produced by methanogenic bacteria that makes it to the surface relative to the amount of methane that is oxidized by methanotrophic bacteria before reaching the atmosphere.[12] This ratio is in turn affected by the other controlling factors of methane in the environment. Additionally, pathways of methane emission affect how the methane travels into the atmosphere and thus have an equal effect on methane flux in wetlands.

Water table

The first controlling factor to consider is the level of the water table. Not only does pool and water table location determine the areas where methane production or oxidation may take place, but it also determines how quickly methane can diffuse into the air. When traveling through water, the methane molecules run into the quickly moving water molecules and thus take a longer time to reach the surface. Travel through soil, however, is much easier and results in easier diffusion into the atmosphere. This theory of movement is supported by observations made in wetlands where significant fluxes of methane occurred after a drop in the water table due to drought.[12] If the water table is at or above the surface, then methane transport begins to take place primarily through ebullition and vascular or pressurized plant mediated transport, with high levels of emission occurring during the day from plants that use pressurized ventilation.[12]

Temperature

Temperature is also an important factor to consider as the environmental temperature—and temperature of the soil in particular—affects the metabolic rate of production or consumption by bacteria. Additionally, because methane fluxes occur annually with the seasons, evidence is provided that suggests that the temperature changing coupled with water table level work together to cause and control the seasonal cycles.[41]

Substrate composition

The composition of soil and substrate availability change the nutrients available for methanogenic and methanotrophic bacteria, and thus directly affects the rate of methane production and consumption. For example, wetlands soils with high levels of acetate or hydrogen and carbon dioxide are conducive to methane production. Additionally, the type of plant life and amount of plant decomposition affects the nutrients available to the bacteria as well as the acidity. Plant leachates such as phenolic compounds from Sphagnum can also interact with soil characteristics to influence methane production and consumption.[42] A constant availability of cellulose and a soil pH of about 6.0 have been determined to provide optimum conditions for methane production and consumption; however, substrate quality can be overridden by other factors.[12] Soil pH and composition must still be compared to the effects of water table and temperature.

Net ecosystem production

Net ecosystem production (NEP) and climate changes are the all encompassing factors that have been shown to have a direct relationship with methane emissions from wetlands. In wetlands with high water tables, NEP has been shown to increase and decrease with methane emissions, most likely due to the fact that both NEP and methane emissions flux with substrate availability and soil composition. In wetlands with lower water tables, the movement of oxygen in and out of the soil can increase the oxidation of methane and the inhibition of methanogenesis, nulling the relationship between methane emission and NEP because methane production becomes dependent upon factors deep within the soil.

A changing climate affects many factors within the ecosystem, including water table, temperature, and plant composition within the wetland—all factors that affect methane emissions. However, climate change can also affect the amount of carbon dioxide in the surrounding atmosphere, which would in turn decrease the addition of methane into the atmosphere, as shown by an 80% decrease in methane flux in areas of doubled carbon dioxide levels.[12]

Causes for additional emissions

Human development of wetlands

Humans often drain wetlands in the name of development, housing, and agriculture. By draining wetlands, the water table is thus lowered, increasing consumption of methane by the methanotrophic bacteria in the soil.[12] However, as a result of draining, water saturated ditches develop, which due to the warm, moist environment, end up emitting a large amount of methane.[12] Therefore, the actual effect on methane emission strongly ends up depending on several factors. If the drains are not spaced far enough apart, then saturated ditches will form, creating mini wetland environments. Additionally, if the water table is lowered significantly enough, then the wetland can actually be transformed from a source of methane into a sink that consumes methane. Finally, the actual composition of the original wetland changes how the surrounding environment is affected by the draining and human development.[citation needed]

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エアリンガス132便USエアウェイズ1170便Aer Lingus Flight 132US Airways Flight 1170事件・インシデントの概要日付 2005年6月9日 (2005-06-09)概要 ATCエラー、ニアミス現場 アメリカ合衆国・マサチューセッツ州ボストンジェネラル・エドワード・ローレンス・ローガン国際空港 北緯42度21分31秒 西経70度59分49秒 / 北緯42.35861度 西経70.99694度 / 42.35861; -70.99694座標: 北緯42...

 

Nishi-Nippon Railroad

Japanese railway company Not to be confused with West Japan Railway Company, which has a similar Japanese name. You can help expand this article with text translated from the corresponding article in Japanese. (November 2022) Click [show] for important translation instructions. Machine translation, like DeepL or Google Translate, is a useful starting point for translations, but translators must revise errors as necessary and confirm that the translation is accurate, rather than simply co...

 

Playoffs 2009 (Bolivia)

El Torneo de Playoffs 2009 también conocido como Copa de la Liga[1]​ fue la segunda edición de este certamen en Bolivia por medio del cual se busca definir el tercer cupo por este país para la Copa Libertadores 2010. Se juega de noviembre a diciembre, y aunque la voz inglesa playoff se traduce como eliminación directa, en este caso se jugará también un repechaje entre los mejores perdedores. En todas las fases (incluyendo el ordenamiento de los perdedores para el repechaje) el gan...

Irakleio railway station

Railway station in Athens, Greece For the Athens Metro station, see Irakleio metro station. ΗράκλειοIraklioGeneral informationLocationIrakleio, 141 22, North AthensCoordinates38°03′26″N 23°46′17″E / 38.057227°N 23.771267°E / 38.057227; 23.771267Owned byGAIAOSE[1]Line(s)Airport–Patras railway[2]Platforms2Tracks3Train operatorsHellenic TrainConstructionPlatform levels2ParkingYesBicycle facilitiesNoAccessible Other informationStatusSt...

 

Bishan Depot

Mass Rapid Transit train depot in Bishan, Singapore Bishan DepotOverview of the depot as viewed from the mainline tracks, October 2020LocationLocation300 Bishan Road, Singapore 579828Coordinates1°21′19.03″N 103°51′14.43″E / 1.3552861°N 103.8540083°E / 1.3552861; 103.8540083CharacteristicsOwnerLand Transport AuthorityOperatorSMRT Trains Ltd (SMRT Corporation)TypeAt-GradeRoadsAng Mo Kio Ave 1, Bishan RoadRolling stockKawasaki Heavy Industries C151Siemens C651...

 

Sentimen anti-Jepang di Korea

Sebuah spanduk anti-Jepang dalam bahasa Korea. Sentimen anti-Jepang di Korea (bahasa Korea: 반일감정; Hanja:反日感情, Banil gamjeong) merujuk kepada sentimen anti-Jepang dalam masyarakat Korea, yang bermula dari sentimen sejarah, budaya dan nasionalistik. Cikal bakal sikap anti-Jepang di Korea bermula dari dampak penyerbuan pembajak Jepang dan kemudian invasi Korea oleh Jepang 1592−98. Sentimen dalam masyarakat kontemporer kebanyakan diatributkan kepaa zaman kekuasaan Jepang di ...

Piala Dunia Antarklub FIFA 2022

Piala Dunia Antarklub FIFA 2022FIFA Club World Cup Morocco 2022presented by Visit Saudiكأس العالم للأندية لكرة القدمالمغرب 2022Informasi turnamenTuan rumahMarokoJadwalpenyelenggaraan1–11 Februari 2023Jumlahtim peserta7 (dari 6 konfederasi)Tempatpenyelenggaraan2 (di 2 kota)Hasil turnamenJuara Real Madrid (gelar ke-5)Tempat kedua Al-HilalTempat ketiga FlamengoTempat keempat Al AhlyStatistik turnamenJumlahpertandingan7Jumlah gol30 (4,29 per pertand...

 

Kristie Moore

Canadian curler Kristie MooreCurlerBorn (1979-04-22) April 22, 1979 (age 44)Grande Prairie, AlbertaTeamCurling clubGrande Prairie CC,[1] Grande Prairie, ABSkipCasey ScheideggerThirdKate HoganSecondJessie HaughianLeadTaylor McDonaldAlternateKristie MooreCurling career Member Association Alberta (1996-2015; 2017-present)  Saskatchewan (2015-2017)Hearts appearances5 (2000, 2013, 2018, 2019, 2023)Top CTRS ranking5th (2018-19)Grand Slam victories1 (2011 Manitoba Lotteries) M...

 

Championnat d'Asie et d'Océanie féminin de volley-ball 1993

Cet article est une ébauche concernant une compétition de volley-ball. Vous pouvez partager vos connaissances en l’améliorant (comment ?) selon les recommandations des projets correspondants. Championnat d'Asie et d'Océanie 1993 Généralités Sport Volley-ball Organisateur(s) AVC Éditions 7e Lieu(x) République populaire de Chine Date du 24 juillet 1993au 31 juillet 1993 Participants 8 équipes Site(s) Shanghai Palmarès Vainqueur Chine Navigation Bangkok 1991 Chiang Mai 1995 mod...

Hamada Domain

Administrative division in western Japan during the Edo period (1619-1866) Hamada Domain浜田藩Domain of Japan1619–1866Surviving gate of Hamada Castle Mon of the Ochi-Matsudaira clan CapitalHamada CastleArea • Coordinates34°54′10.47″N 132°4′23.97″E / 34.9029083°N 132.0733250°E / 34.9029083; 132.0733250 HistoryHistorical eraEdo period• Established 1619• Abolition of the han system 1866 Contained within • Provinc...

 

1917 Princeton Tigers football team

American college football season 1917 Princeton Tigers footballConferenceIndependentRecord2–0Head coachKeene Fitzpatrick (1st season)CaptainJack WinnHome stadiumPalmer StadiumSeasons← 19161918 → 1917 Eastern college football independents records vte Conf Overall Team W   L   T W   L   T Pittsburgh   –   10 – 0 – 0 Williams   –   7 – 0 – 1 Yale   –   3 – 0 –...

 

Bijan Kumar Mukherjea

Bijan Kumar MukherjeaKetua Hakim Mahkamah Agung IndiaMasa jabatan23 Desember 1954 – 31 Januari 1956 Informasi pribadiKebangsaanIndiaProfesiHakimSunting kotak info • L • B Bijan Kumar Mukherjea adalah hakim Mahkamah Agung India. Ia diangkat sebagai hakim di mahkamah tersebut pada tanggal 26 Januari 1950. Ia lalu terpilih sebagai Ketua Hakim Mahkamah Agung India pada tanggal 23 Desember 1954. Masa baktinya sebagai hakim di mahkamah tersebut kemudian berakhir pada tangga...

Chile at the 1952 Summer Olympics

Sporting event delegationChile at the1952 Summer OlympicsIOC codeCHINOCChilean Olympic CommitteeWebsitewww.coch.cl (in Spanish)in HelsinkiCompetitors59 (55 men and 4 women) in 9 sportsFlag bearer Adriana MillardMedalsRanked 31st Gold 0 Silver 2 Bronze 0 Total 2 Summer Olympics appearances (overview)18961900–190819121920192419281932193619481952195619601964196819721976198019841988199219962000200420082012201620202024 Chile at the 1952 Summer Olympics in Helsinki, Finland was the nati...

 

Dutchflyer

Rail-sea-rail service between Netherlands and the UK Dutchflyer Map of the Dutch Flyer rail & sea routeover the North SeaMain region(s)London, East Anglia, South Holland, North HollandParent companyGreater AngliaNederlandse SpoorwegenRotterdamse Elektrische TramStena LineOtherWebsitewww.stenaline.co.uk/ferry-to-holland/rail-and-sail Route map Legend Cambridge Dullingham Newmarket Kennett Norwich Bury St Edmunds Thurston Elmswell Diss LondonLiverpool Street Stratford Stowma...

 

Strategi Solo vs Squad di Free Fire: Cara Menang Mudah!