Atmospheric methane

Summary

Atmospheric methane is the methane present in Earth's atmosphere.[2] The concentration of atmospheric methane is increasing due to methane emissions, and is causing climate change.[3][4] Methane is one of the most potent greenhouse gases.[5]: 82  Methane's radiative forcing (RF) of climate is direct,[6]: 2  and it is the second largest contributor to human-caused climate forcing in the historical period.[6]: 2  Methane is a major source of water vapour in the stratosphere through oxidation;[7] and water vapour adds about 15% to methane's radiative forcing effect.[8] The global warming potential (GWP) for methane is about 84 in terms of its impact over a 20-year timeframe, and 28 in terms of its impact over a 100-year timeframe.[9][10]

Methane (CH4) concentrations in the atmosphere measured by the Advanced Global Atmospheric Gases Experiment (AGAGE) in the lower atmosphere (troposphere) at stations around the world. Values are given as pollution free monthly mean mole fractions in parts-per-billion.[1]

Since the beginning of the Industrial Revolution (around 1750), the methane concentration in the atmosphere has increased by about 160%, and human activities almost entirely caused this increase.[11] Since 1750 methane has contributed 3% of greenhouse gas (GHG) emissions in terms of mass[12] but is responsible for approximately 23% of radiative or climate forcing.[13][14][15] By 2019, global methane concentrations had risen from 722 parts per billion (ppb) in pre-industrial times to 1866 ppb.[16] This is an increase by a factor of 2.6 and the highest value in at least 800,000 years.[17]: 4 [18][19]

Methane increases the amount of ozone (O3) in the troposphere (4 miles (6 km) to 12 miles (19 km) from the Earth's surface) and also in the stratosphere (from the troposphere to 31 miles (50 km) above the Earth's surface).[20] Both water vapour and ozone are GHGs, which in turn add to climate warming.[6]: 2 

Role in climate change

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The warming influence (called radiative forcing) of long-lived greenhouse gases has nearly doubled in 40 years, with carbon dioxide and methane being the dominant drivers of global warming.[21]
 
Radiative forcing (warming influence) of different contributors to climate change through 2019, as reported in the Sixth IPCC assessment report.

Methane (CH4) in the Earth's atmosphere is a powerful greenhouse gas with a global warming potential (GWP) 84 times greater than CO2 over a 20-year time frame.[22][23] Methane is not as persistent as CO2, and tails off to about 28 times greater than CO2 over a 100-year time frame.[10]

Radiative or climate forcing is the scientific concept used to measure the human impact on the environment in watts per square meter (W/m2).[24] It refers to the "difference between solar irradiance absorbed by the Earth and energy radiated back to space"[25] The direct radiative greenhouse gas forcing effect of methane was estimated to be an increase of 0.5 W/m2 relative to the year 1750 (estimate in 2007).[26]: 38 (Figure 2.3) 

In their 2021 "Global Methane Assessment" report, the UNEP and CCAC said that their "understanding of methane's effect on radiative forcing" improved with research by teams led by M. Etminan in 2016,[13] and William Collins in 2018.[6] This resulted in an "upward revision" since the 2014 IPCC Fifth Assessment Report (AR5). The "improved understanding" says that prior estimates of the "overall societal impact of methane emissions" were likely underestimated.[27]: 18 

Etminan et al. published their new calculations for methane's radiative forcing (RF) in a 2016 Geophysical Research Letters journal article which incorporated the shortwave bands of CH4 in measuring forcing, not used in previous, simpler IPCC methods. Their new RF calculations which significantly revised those cited in earlier, successive IPCC reports for well mixed greenhouse gases (WMGHG) forcings by including the shortwave forcing component due to CH4, resulted in estimates that were approximately 20–25% higher.[13] Collins et al. said that CH4 mitigation that reduces atmospheric methane by the end of the century, could "make a substantial difference to the feasibility of achieving the Paris climate targets", and would provide us with more "allowable carbon emissions to 2100".[6]

In addition to the direct heating effect and the normal feedbacks, the methane breaks down to carbon dioxide and water. This water is often above the tropopause, where little water usually reaches. Ramanathan (1998)[28] notes that both water and ice clouds, when formed at cold lower stratospheric temperatures, are extremely efficient in enhancing the atmospheric greenhouse effect. He also notes that there is a distinct possibility that large increases in methane in future may lead to a surface warming that increases nonlinearly with the methane concentration.

Mitigation efforts to reduce short-lived climate pollutants like methane and black carbon would help combat "near-term climate change" and would support Sustainable Development Goals.[29]

Sources

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Main sources of global methane emissions (2008–2017) according to the Global Carbon Project[30]

Any process that results in the production of methane and its release into the atmosphere can be considered a "source". The known sources of methane are predominantly located near the Earth's surface.[12] Two main processes that are responsible for methane production include microorganisms anaerobically converting organic compounds into methane (methanogenesis), which are widespread in aquatic ecosystems, and ruminant animals.

Methane is also released in the Arctic for example from thawing permafrost.

Increasing methane emissions are a major contributor to the rising concentration of greenhouse gases in Earth's atmosphere, and are responsible for up to one-third of near-term global heating.[31][32] During 2019, about 60% (360 million tons) of methane released globally was from human activities, while natural sources contributed about 40% (230 million tons).[33][34] Reducing methane emissions by capturing and utilizing the gas can produce simultaneous environmental and economic benefits.[31][35]

Since the Industrial Revolution, concentrations of methane in the atmosphere have more than doubled, and about 20 percent of the warming the planet has experienced can be attributed to the gas.[36] About one-third (33%) of anthropogenic emissions are from gas release during the extraction and delivery of fossil fuels; mostly due to gas venting and gas leaks from both active fossil fuel infrastructure and orphan wells.[37] Russia is the world's top methane emitter from oil and gas.[38][39]

Animal agriculture is a similarly large source (30%); primarily because of enteric fermentation by ruminant livestock such as cattle and sheep. According to the Global Methane Assessment published in 2021, methane emissions from livestock (including cattle) are the largest sources of agricultural emissions worldwide[40] A single cow can make up to 99 kg of methane gas per year.[41] Ruminant livestock can produce 250 to 500 L of methane per day.[42]

Measurement techniques

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Methane was typically measured using gas chromatography. Gas chromatography is a type of chromatography used for separating or analyzing chemical compounds. It is less expensive in general, compared to more advanced methods, but it is more time and labor-intensive.[citation needed]

Spectroscopic methods were the preferred method for atmospheric gas measurements due to its sensitivity and precision. Also, spectroscopic methods are the only way of remotely sensing the atmospheric gases. Infrared spectroscopy covers a large spectrum of techniques, one of which detects gases based on absorption spectroscopy. There are various methods for spectroscopic methods, including Differential optical absorption spectroscopy, Laser-induced fluorescence, and Fourier Transform Infrared.[citation needed]

[43]

In 2011, cavity ring-down spectroscopy was the most widely used IR absorption technique of detecting methane. It is a form of laser absorption spectroscopy which determines the mole fraction to the order of parts per trillion.

Global monitoring

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Methane concentration at NOAA's Mauna Loa observatory through July 2021: A record-high of 1912 ppb was reached in December 2020.[44]

CH4 has been measured directly in the environment since the 1970s.[45][11] The Earth's atmospheric methane concentration has increased 160% since preindustrial levels in the mid-18th century.[11]

Long term atmospheric measurements of methane by NOAA show that the build up of methane nearly tripled since pre-industrial times since 1750.[46] In 1991 and 1998 there was a sudden growth rate of methane representing a doubling of growth rates in previous years.[46] The June 15, 1991 eruption of Mount Pinatubo, measuring VEI-6—was the second-largest terrestrial eruption of the 20th century.[47] In 2007 it was reported that unprecedented warm temperatures in 1998—the warmest year since surface records were recorded—could have induced elevated methane emissions, along with an increase in wetland and rice field emissions and the amount of biomass burning.[48]

Data from 2007 suggested methane concentrations were beginning to rise again.[49] This was confirmed in 2010 when a study showed methane levels were on the rise for the 3 years 2007 to 2009. After a decade of near-zero growth in methane levels, "globally averaged atmospheric methane increased by [approximately] 7 nmol/mol per year during 2007 and 2008. During the first half of 2009, globally averaged atmospheric CH4 was [approximately] 7 nmol/mol greater than it was in 2008, suggesting that the increase will continue in 2009."[50] From 2015 to 2019 sharp rises in levels of atmospheric methane have been recorded.[51]

In 2010, methane levels in the Arctic were measured at 1850 nmol/mol which is over twice as high as at any time in the last 400,000 years.[citation needed] According to the IPCC AR5, since 2011 concentrations continued to increase. After 2014, the increase accelerated and by 2017, it reached 1,850 (parts per billion) ppb.[52] The annual average for methane (CH4) was 1866 ppb in 2019 and scientists reported with "very high confidence" that concentrations of CH4 were higher than at any time in at least 800,000 years.[14] The largest annual increase occurred in 2021 with current concentrations reaching a record 260% of pre-industrial—with the overwhelming percentage caused by human activity.[11]

In 2013, IPCC scientists said with "very high confidence", that concentrations of atmospheric methane CH4 "exceeded the pre-industrial levels by about 150% which represented "levels unprecedented in at least the last 800,000 years."[14][53] The globally averaged concentration of methane in Earth's atmosphere increased by about 150% from 722 ± 25 ppb in 1750 to 1803.1 ± 0.6 ppb in 2011.[54][55] As of 2016, methane contributed radiative forcing of 0.62 ± 14% Wm−2,[13] or about 20% of the total radiative forcing from all of the long-lived and globally mixed greenhouse gases.[10] The atmospheric methane concentration has continued to increase since 2011 to an average global concentration of 1911.8 ± 0.6 ppb as of 2022.[16] The May 2021 peak was 1891.6 ppb, while the April 2022 peak was 1909.4 ppb, a 0.9% increase.[55]

 
Annual atmospheric methane concentrations from 1990 to 2021.

The Global Carbon Project consortium produces the Global Methane Budget. Working with over fifty international research institutions and 100 stations globally, it updates the methane budget every few years.[56]

In 2013, the balance between sources and sinks of methane was not yet fully understood. Scientists were unable to explain why the atmospheric concentration of methane had temporarily ceased to increase.[57]

The focus on the role of methane in anthropogenic climate change has become more relevant since the mid-2010s.[58]

Natural sinks or removal of atmospheric methane

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The amount of methane in the atmosphere is the result of a balance between the production of methane on the Earth's surface—its source—and the destruction or removal of methane, mainly in the atmosphere—its sink— in an atmospheric chemical process.[59]

Another major natural sink is through oxidation by methanotrophic or methane-consuming bacteria in Earth's soils.

 
NASA computer models from 2005, calculated based on information available at that time, show the amount of methane (parts per million by volume) at the surface (top) and in the stratosphere (bottom)[59]

These 2005 NASA computer model simulations—calculated based on data available at that time—illustrate how methane is destroyed as it rises.

As air rises in the tropics, methane is carried upwards through the troposphere—the lowest portion of Earth's atmosphere which is 4 miles (6.4 km) to 12 miles (19 km) from the Earth's surface, into the lower stratosphere—the ozone layer—and then the upper portion of the stratosphere.[59]

This atmospheric chemical process is the most effective methane sink, as it removes 90% of atmospheric methane.[57] This global destruction of atmospheric methane mainly occurs in the troposphere.[57]

Methane molecules react with hydroxyl radicals (OH)—the "major chemical scavenger in the troposphere" that "controls the atmospheric lifetime of most gases in the troposphere".[60] Through this CH4 oxidation process, atmospheric methane is destroyed and water vapor and carbon dioxide are produced.

While this decreases the concentration of methane in the atmosphere, it is unclear if this leads to a net positive increase in radiative forcing because both water vapor and carbon dioxide are more powerful GHGs factors in terms of affecting the warming of Earth.

This additional water vapor in the stratosphere caused by CH4 oxidation, adds approximately 15% to methane's radiative forcing effect.[61][7]

By the 1980s, the global warming problem had been transformed by the inclusion of methane and other non-CO2 trace-gases—CFCs, N2O, and O3— on global warming, instead of focusing primarily on carbon dioxide.[62][63] Both water and ice clouds, when formed at cold lower stratospheric temperatures, have a significant impact by increasing the atmospheric greenhouse effect. Large increases in future methane could lead to a surface warming that increases nonlinearly with the methane concentration.[62][63]

Methane also affects the degradation of the ozone layer—the lowest layer of the stratosphere from about 15 to 35 kilometers (9 to 22 mi) above Earth, just above the troposphere.[64] NASA researchers in 2001, had said that this process was enhanced by global warming, because warmer air holds more water vapor than colder air, so the amount of water vapor in the atmosphere increases as it is warmed by the greenhouse effect. Their climate models based on data available at that time, had indicated that carbon dioxide and methane enhanced the transport of water into the stratosphere.[65]

Atmospheric methane could last about 120 years in the stratosphere until it is eventually destroyed through the hydroxyl radicals oxidation process.[66]

Mean lifespan

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Estimated atmospheric methane lifetime before the industrial era (shaded area); changes in methane lifetime since 1850 as simulated by a climate model (blue line), and the reconciled graph (red line).[67]

There are different ways to quantify the period of time that methane impacts the atmosphere. The average time that a physical methane molecule is in the atmosphere is estimated to be around 9.6 years.[68][69][67] However, the average time that the atmosphere will be affected by the emission of that molecule before reaching equilibrium – known as its 'perturbation lifetime' – is approximately twelve years.[29][70]

The reaction of methane and chlorine atoms acts as a primary sink of Cl atoms and is a primary source of hydrochloric acid (HCl) in the stratosphere.[71]

CH4 + Cl → CH3 + HCl

The HCl produced in this reaction leads to catalytic ozone destruction in the stratosphere.[66]

Methanotrophs in soils and sediments

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Methane releases in the Laptev Sea are typically consumed within the sediment by methanotrophs. Areas with high sedimentation (top) subject their microbial communities to continual disturbance, and so they are the most likely to see active fluxes, whether with (right) or without active upward flow (left). Even so, the annual release may be limited to 1000 tonnes or less.[72]

Soils act as a major sink for atmospheric methane through the methanotrophic bacteria that reside within them. This occurs with two different types of bacteria. "High capacity-low affinity" methanotrophic bacteria grow in areas of high methane concentration, such as waterlogged soils in wetlands and other moist environments. And in areas of low methane concentration, "low capacity-high affinity" methanotrophic bacteria make use of the methane in the atmosphere to grow, rather than relying on methane in their immediate environment.[73] Methane oxidation allows methanotrophic bacteria to use methane as a source of energy, reacting methane with oxygen and as a result producing carbon dioxide and water.

CH4 + 2O2 → CO2 + 2H2O

Forest soils act as good sinks for atmospheric methane because soils are optimally moist for methanotroph activity, and the movement of gases between soil and atmosphere (soil diffusivity) is high.[73] With a lower water table, any methane in the soil has to make it past the methanotrophic bacteria before it can reach the atmosphere. Wetland soils, however, are often sources of atmospheric methane rather than sinks because the water table is much higher, and the methane can be diffused fairly easily into the air without having to compete with the soil's methanotrophs.[73]

Methanotrophic bacteria also occur in the underwater sediments. Their presence can often efficiently limit emissions from sources such as the underwater permafrost in areas like the Laptev Sea.[72]

Removal technologies

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Atmospheric methane removal is a category of potential approaches being researched to accelerate the breakdown of methane that is in the atmosphere, for the purpose of mitigating some of the impacts of climate change.[74]

Atmospheric methane has increased since pre-industrial times from 0.7 ppm to 1.9 ppm.[75] From 2010 to 2019, methane emissions caused 0.5 °C (about 30%) of observed global warming.[76][77] Global methane emissions approached a record 600 Tg CH4 per year in 2017.[74]

Methane concentrations in the geologic past

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Compilation of paleoclimatology data of methane

From 1996 to 2004, researchers in the European Project for Ice Coring in Antarctica (EPICA) project were able to drill and analyze gases trapped in the ice cores in Antarctica to reconstruct GHG concentrations in the atmosphere over the past 800,000 years".[78] They found that prior to approximately 900,000 years ago, the cycle of ice ages followed by relatively short warm periods lasted about 40,000 years, but by 800,000 years ago the time interval changed dramatically to cycles that lasted 100,000 years.[78] There were low values of GHG in ice ages, and high values during the warm periods.[78]

This 2016 EPA illustration above is a compilation of paleoclimatology showing methane concentrations over time based on analysis of gas bubbles from[79] EPICA Dome C, Antarctica—approximately 797,446 BCE to 1937 CE,[80] Law Dome, Antarctica—approximately 1008 CE to 1980 CE[81] Cape Grim, Australia—1985 CE to 2015 CE[82] Mauna Loa, Hawaii—1984 CE to 2015 CE[83] and Shetland Islands, Scotland: 1993 CE to 2001 CE[84]

 
The impact of CH4 atmospheric methane concentrations on global temperature increase may be far greater than previously estimated.[2][85]

The massive and rapid release of large volumes of methane gas from such sediments into the atmosphere has been suggested as a possible cause for rapid global warming events in the Earth's distant past, such as the Paleocene–Eocene Thermal Maximum,[86] and the Great Dying.[87]

In 2001, NASA's Goddard Institute for Space Studies and Columbia University's Center for Climate Systems Research scientists confirmed that other greenhouse gases apart from carbon dioxide were important factors in climate change in research presented at the annual meeting of the American Geophysical Union (AGU).[88] They offered a theory on the 100,000-year long Paleocene–Eocene Thermal Maximum that occurred approximately 55 million years ago. They posited that there was a vast release of methane that had previously been kept stable through "cold temperatures and high pressure...beneath the ocean floor". This methane release into the atmosphere resulted in the warming of the earth. A 2009 journal article in Science, confirmed NASA research that the contribution of methane to global warming had previously been underestimated.[89][90]

Early in the Earth's history carbon dioxide and methane likely produced a greenhouse effect. The carbon dioxide would have been produced by volcanoes and the methane by early microbes. During this time, Earth's earliest life appeared.[91] According to a 2003 article in the journal Geology, these first, ancient bacteria added to the methane concentration by converting hydrogen and carbon dioxide into methane and water. Oxygen did not become a major part of the atmosphere until photosynthetic organisms evolved later in Earth's history. With no oxygen, methane stayed in the atmosphere longer and at higher concentrations than it does today.[92]

References

edit
  1. ^ "AGAGE Data & Figures | Advanced Global Atmospheric Gases Experiment". agage.mit.edu. Retrieved July 2, 2024.
  2. ^ Dlugokencky, Ed (December 5, 2016). "Trends in Atmospheric Methane". Global Greenhouse Gas Reference Network. NOAA Earth System Research Laboratory. Retrieved December 22, 2016.
  3. ^ Methane Tracker 2021. IEA (Report). Paris. 2021. Retrieved March 21, 2023.License: CC BY 4.0
  4. ^ "Methane in the atmosphere is surging, and that's got scientists worried". Los Angeles Times. March 1, 2019. Retrieved March 1, 2019.
  5. ^ "IPCC AR4 SYR Appendix Glossary" (PDF). 2007. Archived from the original (PDF) on November 17, 2018. Retrieved December 14, 2008.
  6. ^ a b c d e Collins, William J.; Webber, Christopher P.; Cox, Peter M.; Huntingford, Chris; Lowe, Jason; Sitch, Stephen; Chadburn, Sarah E.; Comyn-Platt, Edward; Harper, Anna B.; Hayman, Garry; Powell, Tom (April 20, 2018). "Increased importance of methane reduction for a 1.5 degree target". Environmental Research Letters. 13 (5): 054003. Bibcode:2018ERL....13e4003C. doi:10.1088/1748-9326/aab89c. hdl:10871/34408. ISSN 1748-9326. S2CID 53683162. Retrieved March 19, 2023.
  7. ^ a b Noël, Stefan; Weigel, Katja; et al. (2017). "Water Vapour and Methane Coupling in the Stratosphere observed with SCIAMACHY Solar Occultation Measurements" (PDF). Atmospheric Chemistry and Physics (18): 4463–4476. doi:10.5194/acp-18-4463-2018. Archived (PDF) from the original on October 9, 2022. Retrieved August 22, 2021.
  8. ^ Myhre, Gunnar; et al. (January 9, 2007). "Radiative forcing due to stratospheric water vapour from CH4 oxidation". Geophysical Research Letters. 34 (1). Bibcode:2007GeoRL..34.1807M. doi:10.1029/2006GL027472. S2CID 59133913.
  9. ^ "Methane: The other important greenhouse gas". Environmental Defence Fund.
  10. ^ a b c Myhre, Gunnar; et al. (2013). Stocker, T.F.; Qin, D.; Plattner, G.-K.; Tignor, M.; Allen, S.K.; Boschung, J.; Nauels, A.; Xia, Y.; Bex, V.; Midgley, P.M. (eds.). Anthropogenic and Natural Radiative Forcing (PDF). Cambridge, United Kingdom and New York, USA: Cambridge University Press. Retrieved December 22, 2016. {{cite book}}: |work= ignored (help) See Table 8.7.
  11. ^ a b c d Global Methane Assessment (PDF). United Nations Environment Programme and Climate and Clean Air Coalition (Report). Nairobi. 2022. p. 12. Retrieved March 15, 2023.
  12. ^ a b Saunois, M.; Bousquet, M.; Poulter, B.; et al. (December 12, 2016). "The Global Methane Budget 2000–2012". Earth System Science Data. 8 (2): 697–751. Bibcode:2016ESSD....8..697S. doi:10.5194/essd-8-697-2016. hdl:1721.1/108811. ISSN 1866-3508. Retrieved August 28, 2020.
  13. ^ a b c d Etminan, M.; Myhre, G.; Highwood, E. J.; Shine, K. P. (December 27, 2016). "Radiative forcing of carbon dioxide, methane, and nitrous oxide: A significant revision of the methane radiative forcing". Geophysical Research Letters. 43 (24): 12, 614–12, 623. Bibcode:2016GeoRL..4312614E. doi:10.1002/2016gl071930. ISSN 0094-8276.
  14. ^ a b c "Climate Change 2021. The Physical Science Basis. Summary for Policymakers. Working Group I contribution to the WGI Sixth Assessment Report of the Intergovernmental Panel on Climate Change". IPCC. The Intergovernmental Panel on Climate Change. Archived from the original on August 22, 2021. Retrieved August 22, 2021.
  15. ^ Ritchie, Hannah; Roser, Max; Rosado, Pablo (May 11, 2020). "CO₂ and Greenhouse Gas Emissions". Our World in Data. Retrieved March 19, 2023.
  16. ^ a b Laboratory, US Department of Commerce, NOAA, Earth System Research (July 5, 2023). "Globally averaged marine surface annual mean data". ESRL Global Monitoring Division – Global Greenhouse Gas Reference Network. Retrieved July 6, 2023.{{cite web}}: CS1 maint: multiple names: authors list (link)
  17. ^ Synthesis Report of the IPCC Sixth Assessment Report (AR6) (PDF) (Report). Summary for Policy Makers. March 19, 2023. p. 36. Archived from the original (PDF) on March 20, 2023. Retrieved March 20, 2023.
  18. ^ IPCC AR5 WG1 (2013). "Climate Change 2013: The Physical Science Basis – Summary for Policymakers" (PDF). Cambridge University Press.{{cite web}}: CS1 maint: numeric names: authors list (link)
  19. ^ Mann, Michael E. (ed.). "Radiative forcing". Encyclopædia Britannica. Retrieved March 19, 2023.
  20. ^ Wuebbles, Donald J.; Tamaresis, John S. (1993). "The Role of Methane in the Global Environment". In Khalil, M. A. K. (ed.). Atmospheric Methane: Sources, Sinks, and Role in Global Change. NATO ASI Series. Berlin, Heidelberg: Springer. pp. 469–513. doi:10.1007/978-3-642-84605-2_20. ISBN 978-3-642-84605-2.
  21. ^ "The NOAA Annual Greenhouse Gas Index (AGGI)". NOAA.gov. National Oceanic and Atmospheric Administration (NOAA). 2024. Archived from the original on October 5, 2024.
  22. ^ Stocker; et al. "Climate Change 2013: The Physical Science Basis. Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change" (PDF). ipcc.ch. Cambridge University Press. Retrieved October 19, 2021.
  23. ^ Stocker, Thomas (ed.). Climate change 2013 : the physical science basis : Working Group I contribution to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change. New York. p. 166. ISBN 978-1-10741-532-4. OCLC 881236891.
  24. ^ Drew, Shindell (2013). "Climate Change 2013: The Physical Science Basis – Working Group 1 contribution to the IPCC Fifth Assessment Report: Radiative Forcing in the AR5" (PDF). Department of Environmental Sciences, School of Environmental and Biological Sciences. envsci.rutgers.edu. Rutgers University. Fifth Assessment Report (AR5). Archived (PDF) from the original on March 4, 2016. Retrieved September 15, 2016.
  25. ^ Rebecca, Lindsey (January 14, 2009). "Climate and Earth's Energy Budget: Feature Articles". earthobservatory.nasa.gov. Archived from the original on April 10, 2020. Retrieved April 3, 2018.
  26. ^ "Climate Change Synthesis Report 2007" (PDF). IPCC AR4. United Nations Environment Programme.
  27. ^ Shindell, Drew, ed. (May 6, 2021). Global Methane Assessment: Benefits and Costs of Mitigating Methane Emissions. United Nations Environment Programme (Report). p. 173. ISBN 978-92-807-3854-4.
  28. ^ "Ramanathan" (PDF). Trace-Gas Greenhouse Effect and Global Warming: Underlying Principles and Outstanding Issues. Ambio-Royal Swedish Academy of sciences.
  29. ^ a b "Primer on Short-Lived Climate Pollutants". Climate & Clean Air Coalition. Retrieved March 19, 2023.
  30. ^ Saunois, M.; Stavert, A.R.; Poulter, B.; et al. (July 15, 2020). "The Global Methane Budget 2000–2017". Earth System Science Data (ESSD). 12 (3): 1561–1623. Bibcode:2020ESSD...12.1561S. doi:10.5194/essd-12-1561-2020. hdl:1721.1/124698. ISSN 1866-3508. Retrieved August 28, 2020.
  31. ^ a b "Global Methane Emissions and Mitigation Opportunities" (PDF). Global Methane Initiative. 2020.
  32. ^ IPCC Fifth Assessment Report - Radiative Forcings (AR5 Figure SPM.5) (Report). Intergovernmental Panel on Climate Change. 2013.
  33. ^ "Sources of methane emissions". International Energy Agency. Retrieved August 20, 2020.
  34. ^ "Global Carbon Project (GCP)". www.globalcarbonproject.org. Retrieved July 25, 2019.
  35. ^ Methane - A compelling case for action (Report). International Energy Agency. August 20, 2020.
  36. ^ Borunda, A. (2021, May 03). Methane facts and information. Retrieved April 6, 2022, from [1]
  37. ^ Leber, Rebecca (August 12, 2021). "It's time to freak out about methane emissions". Vox. Retrieved January 5, 2022.
  38. ^ Trakimavicius, Lukas. "Putting a lid on Russia's planet-heating methane emissions". EurActiv. Retrieved July 26, 2023.
  39. ^ Timothy Puko (October 19, 2021). "Who Are the World's Biggest Climate Polluters? Satellites Sweep for Culprits". The Wall Street Journal. Retrieved October 19, 2021. Russia is the world's top source of methane emissions from the oil-and-gas industry
  40. ^ "Yes, cattle are the top source of methane emissions in the US". verifythis.com. November 12, 2021. Retrieved February 26, 2024.
  41. ^ "Cows and Climate Change". UC Davis. June 27, 2019. Retrieved February 26, 2024.
  42. ^ Johnson, K A (August 1, 1995). "Methane emissions from cattle". academic.oup.com. Retrieved April 27, 2023.
  43. ^ Nakaema, Walter M.; Hao, Zuo-Qiang; Rohwetter, Philipp; Wöste, Ludger; Stelmaszczyk, Kamil (January 27, 2011). "PCF-Based Cavity Enhanced Spectroscopic Sensors for Simultaneous Multicomponent Trace Gas Analysis". Sensors. 11 (2): 1620–1640. Bibcode:2011Senso..11.1620N. doi:10.3390/s110201620. ISSN 1424-8220. PMC 3274003. PMID 22319372.
  44. ^ "ESRL/GMD FTP Data Finder". Retrieved March 28, 2017.
  45. ^ Fox-Kemper, B.; Hewitt, H.T.; Xiao, C.; Aðalgeirsdóttir, G.; Drijfhout, S.S.; Edwards, T.L.; Golledge, N.R.; Hemer, M.; Kopp, R.E.; Krinner, G.; Mix, A. (2021). Masson-Delmotte, V.; Zhai, P.; Pirani, A.; Connors, S.L.; Péan, C.; Berger, S.; Caud, N.; Chen, Y.; Goldfarb, L. (eds.). "Chapter 5: Global Carbon and other Biogeochemical Cycles and Feedbacks". Climate Change 2021: The Physical Science Basis. Contribution of Working Group I to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press, Cambridge, UK and New York, NY, USA. doi:10.1017/9781009157896.011. Archived from the original (PDF) on January 20, 2023.
  46. ^ a b "Ch.2 Changes in Atmospheric Constituents and in Radiative Forcing". Climate Change 2007 IPCC Fourth Assessment Report. IPPC. Retrieved January 20, 2017.
  47. ^ "Scientists pinpoint cause of slowing methane emissions". National Oceanic & Atmospheric Administration news Online. September 28, 2006. Archived from the original on May 26, 2007. Retrieved May 23, 2007.
  48. ^ Denman, K.L.; et al. "7. Couplings Between Changes in the Climate System and Biogeochemistry". IPCC AR4 WG1 2007. Retrieved November 4, 2011.
  49. ^ "Annual Greenhouse Gas Index (AGGI) Indicates Sharp Rise in Carbon Dioxide and Methane in 2007". National Oceanic & Atmospheric Administration – Earth System Research Laboratory. April 23, 2008. Retrieved June 16, 2008.
  50. ^ Heidi Blake (February 22, 2010). "Climate change could be accelerated by 'methane time bomb'". The Telegraph. Archived from the original on February 25, 2010.
  51. ^ McKie, Robin (February 17, 2019). "Sharp rise in methane levels threatens world climate targets". The Observer. ISSN 0029-7712. Retrieved July 14, 2019.
  52. ^ Nisbet, E. G.; Manning, M. R.; Dlugokencky, E. J.; Fisher, R. E.; Lowry, D.; Michel, S. E.; Myhre, C. Lund; Platt, S. M.; Allen, G.; Bousquet, P.; Brownlow, R.; Cain, M.; France, J. L.; Hermansen, O.; Hossaini, R.; Jones, A. E.; Levin, I.; Manning, A. C.; Myhre, G.; Pyle, J. A.; Vaughn, B. H.; Warwick, N. J.; White, J. W. C. (2019). "Very Strong Atmospheric Methane Growth in the 4 Years 2014–2017: Implications for the Paris Agreement". Global Biogeochemical Cycles. 33 (3): 318–342. Bibcode:2019GBioC..33..318N. doi:10.1029/2018GB006009. ISSN 1944-9224. S2CID 133716021.
  53. ^ IPCC (2013). Stocker, T. F.; Qin, D.; Plattner, G.-K.; Tignor, M.; et al. (eds.). Climate Change 2013: The Physical Science Basis (PDF) (Report). Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change.
  54. ^ Stocker. "Climate Change 2013: The Physical Science Basis. Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change" (PDF). p. 182.
  55. ^ a b Laboratory, US Department of Commerce, NOAA, Earth System Research (July 5, 2023). "Globally averaged marine surface monthly mean data". ESRL Global Monitoring Division – Global Greenhouse Gas Reference Network. Retrieved July 6, 2023.{{cite web}}: CS1 maint: multiple names: authors list (link)
  56. ^ Friedlingstein, Pierre; O'Sullivan, Michael; Jones, Matthew W.; Andrew, Robbie M.; Gregor, Luke; Hauck (November 11, 2022). "Global Carbon Budget 2022". Earth System Science Data. 14 (11): 4811–4900. Bibcode:2022ESSD...14.4811F. doi:10.5194/essd-14-4811-2022. hdl:20.500.11850/594889. ISSN 1866-3516. Retrieved March 15, 2023.
  57. ^ a b c Kirschke, Stefanie; et al. (September 22, 2013). "Three decades of global methane sources and sinks". Nature Geoscience. 6 (10): 813–823. Bibcode:2013NatGe...6..813K. doi:10.1038/ngeo1955. S2CID 18349059.
  58. ^ Saunois, M; Jackson, B.; Bousquet, P.; Poulter, B.; Canadell, J G (2016). "The growing role of methane in anthropogenic climate change". Environmental Research Letters. Vol. 11, no. 120207. p. 120207. doi:10.1088/1748-9326/11/12/120207.
  59. ^ a b c "GMAO Chemical Forecasts and GEOS–CHEM NRT Simulations for ICARTT (top) and Randy Kawa, NASA GSFC Atmospheric Chemistry and Dynamics Branch (lower)". Archived from the original on March 13, 2005.
  60. ^ Levine, S. "Chemistry of the Hydroxyl Radical (OH) in the Troposphere". In Holland, H.D.; Turekian, K.K. (eds.). Treatise on geochemistry. Vol. 5 (2 ed.). Oxford: Elsevier Science.
  61. ^ Myhre, Gunnar; et al. (January 9, 2007). "Radiative forcing due to stratospheric water vapour from CH4 oxidation". Geophysical Research Letters. 34 (1). Bibcode:2007GeoRL..34.1807M. doi:10.1029/2006GL027472. S2CID 59133913.
  62. ^ a b Ramanathan, V. (1998). "Trace-Gas Greenhouse Effect and Global Warming: Underlying Principles and Outstanding Issues Volvo Environmental Prize Lecture-1997". Ambio. 27 (3): 187–197. ISSN 0044-7447. JSTOR 4314715. Retrieved March 23, 2023.
  63. ^ a b "Ramanathan". Trace-Gas Greenhouse Effect and Global Warming: Underlying Principles and Outstanding Issues. Ambio-Royal Swedish Academy of Sciences.
  64. ^ "Ozone Basics". NOAA. March 20, 2008. Archived from the original on November 21, 2017. Retrieved January 29, 2007.
  65. ^ Shindell, Drew (2001). "Wetter Upper Atmosphere May Delay Global Ozone Recovery". NASA.
  66. ^ a b Rohs, S.; Schiller, C.; Riese, M.; Engel, A.; Schmidt, U.; Wetter, T.; Levin, I.; Nakazawa, T. (July 2006). "Long-term changes of methane and hydrogen in the stratosphere in the period 1978–2003 and their impact on the abundance of stratospheric water vapor" (PDF). Journal of Geophysical Research: Atmospheres. 111 (D14): D14315. Bibcode:2006JGRD..11114315R. doi:10.1029/2005JD006877. D14315.
  67. ^ a b Arora, Vivek K.; Melton, Joe R.; Plummer, David (August 1, 2018). "An assessment of natural methane fluxes simulated by the CLASS-CTEM model". Biogeosciences. 15 (15): 4683–4709. Bibcode:2018BGeo...15.4683A. doi:10.5194/bg-15-4683-2018.
  68. ^ "Methane and Nitrous Oxide Emissions From Natural Sources" (PDF). USA Environmental Protection Agency Office of Atmospheric Programs. April 2010. Archived from the original (PDF) on December 2, 2012. Retrieved January 20, 2017.
  69. ^ Holmes, C. D.; et al. (January 2013). "Future methane, hydroxyl, and their uncertainties: key climate and emission parameters for future predictions" (PDF). Atmospheric Chemistry and Physics. 13 (1): 285–302. Bibcode:2013ACP....13..285H. doi:10.5194/acp-13-285-2013. See Table 2.
  70. ^ Clark, Duncan; Brief, Carbon (January 16, 2012). "How long do greenhouse gases stay in the air?". The Guardian.
  71. ^ Warneck, Peter (2000). Chemistry of the Natural Atmosphere. Academic Press. ISBN 9780127356327.
  72. ^ a b Puglini, Matteo; Brovkin, Victor; Regnier, Pierre; Arndt, Sandra (June 26, 2020). "Assessing the potential for non-turbulent methane escape from the East Siberian Arctic Shelf". Biogeosciences. 17 (12): 3247–3275. Bibcode:2020BGeo...17.3247P. doi:10.5194/bg-17-3247-2020. hdl:21.11116/0000-0003-FC9E-0. S2CID 198415071.
  73. ^ a b c Reay, Dave. "Methane Sinks − Soils". Greenhouse Gas Online. Retrieved December 22, 2016.
  74. ^ a b Jackson, Robert (2021). "Atmospheric methane removal: a research agenda". Philosophical Transactions A. 379 (20200454). Bibcode:2021RSPTA.37900454J. doi:10.1098/rsta.2020.0454. PMC 8473948. PMID 34565221.
  75. ^ "Rising methane could be a sign that Earth's climate is part-way through a 'termination-level transition'". August 14, 2023.
  76. ^ "Figure AR6 WG1". ipcc.ch. Retrieved October 5, 2023.
  77. ^ "Methane and climate change".
  78. ^ a b c "The oldest ice on Earth may be able to solve the puzzle of the planet's climate history". University of Bern. April 2019. Retrieved March 20, 2023.
  79. ^ Climate Change Indicators in the United States: Atmospheric Concentrations of Greenhouse Gases (PDF) (Report). August 2016. Retrieved March 20, 2023.
  80. ^ Loulergue, Laetitia; Schilt, Adrian; Spahni, Renato; Masson-Delmotte, Valérie; Blunier, Thomas; Lemieux, Bénédicte; Barnola, Jean-Marc; Raynaud, Dominique; Stocker, Thomas F.; Chappellaz, Jérôme (May 15, 2008). "Orbital and millennial-scale features of atmospheric CH4 over the past 800,000 years". Nature. 453 (7193): 383–386. Bibcode:2008Natur.453..383L. doi:10.1038/nature06950. ISSN 1476-4687. PMID 18480822. S2CID 205213265. Retrieved March 20, 2023.
  81. ^ Etheridge, D.; Steele, L.; Francey, R.; Langenfelds, R. (2002). Historic CH4 Records from Antarctic and Greenland Ice Cores, Antarctic Firn Data, and Archived Air Samples from Cape Grim, Tasmania (Report). Trends: A compendium of data on global change. Oak Ridge, TN: Environmental System Science Data Infrastructure for a Virtual Ecosystem; Carbon Dioxide Information Analysis Center (CDIAC), Oak Ridge National Laboratory (ORNL). doi:10.3334/CDIAC/ATG.030. Retrieved March 21, 2023.
  82. ^ Monthly mean CH4 concentrations for Cape Grim, Australia. National Oceanic and Atmospheric Administration (Report). 2016.
  83. ^ Monthly mean CH4 concentrations for Mauna Loa, Hawaii. National Oceanic and Atmospheric Administration (Report). 2016.
  84. ^ Steele, L.P.; Krummel, P.B.; Langenfelds, R.L. (October 2002). Atmospheric methane record from Shetland Islands, Scotland. Trends: A compendium of data on global change. Oak Ridge, TN. Retrieved March 20, 2023. {{cite book}}: |work= ignored (help)CS1 maint: location missing publisher (link)
  85. ^ "Methane | Reg Morrison". regmorrison.edublogs.org. Retrieved November 24, 2018.
  86. ^ Bowen, Gabriel J.; et al. (December 15, 2014). "Two massive, rapid releases of carbon during the onset of the Palaeocene–Eocene thermal maximum". Nature Geoscience. 8 (1): 44–47. Bibcode:2015NatGe...8...44B. doi:10.1038/ngeo2316.
  87. ^ Benton, Michael J.; Twitchett, Richard J. (July 2003). "How to kill (almost) all life: the end-Permian extinction event". Trends in Ecology & Evolution. 18 (7): 358–365. doi:10.1016/S0169-5347(03)00093-4.
  88. ^ "Methane Explosion Warmed The Prehistoric Earth, Possible Again". NASA/Goddard Space Flight Center, EOS Project Science Office (Press release). December 12, 2001. Retrieved March 22, 2023 – via ScienceDaily.
  89. ^ Shindell, 2 Greg; Faluvegi, G.; Koch, Dorothy M.; Schmidt, Gavin A.; Unger, Nadine; Bauer, Susanne E. (October 30, 2009). "Improved Attribution of Climate Forcing to Emissions". Science. 326 (5953): 716–718. Bibcode:2009Sci...326..716S. doi:10.1126/science.1174760. PMID 19900930. S2CID 30881469.{{cite journal}}: CS1 maint: numeric names: authors list (link)
  90. ^ Vergano, Dan (October 29, 2009). "Methane's role in global warming underestimated". USA Today.
  91. ^ Gale, Joseph (2009). Astrobiology of Earth: the emergence, evolution, and future of life on a planet in turmoil. Oxford: Oxford University Press. ISBN 978-0-19-920580-6.
  92. ^ Pavlov, Alexander A.; et al. (January 2003). "Methane-rich Proterozoic atmosphere?". Geology. 31 (1): 87–90. Bibcode:2003Geo....31...87P. doi:10.1130/0091-7613(2003)031<0087:MRPA>2.0.CO;2.