论文信息 - The Global Methane Budget 2000–2017

The Global Methane Budget 2000–2017

Abstract. Understanding and quantifying the global methane (CH4) budget is important for assessing realistic pathways to mitigate climate change. Atmospheric emissions and concentrations of CH4 continue to increase, making CH4 the second most important human-influenced greenhouse gas in terms of climate forcing, after carbon dioxide (CO2). The relative importance of CH4 compared to CO2 depends on its shorter atmospheric lifetime, stronger warming potential, and variations in atmospheric growth rate over the past decade, the causes of which are still debated. Two major challenges in reducing uncertainties in the atmospheric growth rate arise from the variety of geographically overlapping CH4 sources and from the destruction of CH4 by short-lived hydroxyl radicals (OH). To address these challenges, we have established a consortium of multidisciplinary scientists under the umbrella of the Global Carbon Project to synthesize and stimulate new research aimed at improving and regularly updating the global methane budget. Following Saunois et al. (2016), we present here the second version of the living review paper dedicated to the decadal methane budget, integrating results of top-down studies (atmospheric observations within an atmospheric inverse-modelling framework) and bottom-up estimates (including process-based models for estimating land surface emissions and atmospheric chemistry, inventories of anthropogenic emissions, and data-driven extrapolations). For the 2008–2017 decade, global methane emissions are estimated by atmospheric inversions (a top-down approach) to be 576 Tg CH4 yr−1 (range 550–594, corresponding to the minimum and maximum estimates of the model ensemble). Of this total, 359 Tg CH4 yr−1 or ∼ 60 % is attributed to anthropogenic sources, that is emissions caused by direct human activity (i.e. anthropogenic emissions; range 336–376 Tg CH4 yr−1 or 50 %–65 %). The mean annual total emission for the new decade (2008–2017) is 29 Tg CH4 yr−1 larger than our estimate for the previous decade (2000–2009), and 24 Tg CH4 yr−1 larger than the one reported in the previous budget for 2003–2012 (Saunois et al., 2016). Since 2012, global CH4 emissions have been tracking the warmest scenarios assessed by the Intergovernmental Panel on Climate Change. Bottom-up methods suggest almost 30 % larger global emissions (737 Tg CH4 yr−1, range 594–881) than top-down inversion methods. Indeed, bottom-up estimates for natural sources such as natural wetlands, other inland water systems, and geological sources are higher than top-down estimates. The atmospheric constraints on the top-down budget suggest that at least some of these bottom-up emissions are overestimated. The latitudinal distribution of atmospheric observation-based emissions indicates a predominance of tropical emissions (∼ 65 % of the global budget, < 30∘ N) compared to mid-latitudes (∼ 30 %, 30–60∘ N) and high northern latitudes (∼ 4 %, 60–90∘ N). The most important source of uncertainty in the methane budget is attributable to natural emissions, especially those from wetlands and other inland waters. Some of our global source estimates are smaller than those in previously published budgets (Saunois et al., 2016; Kirschke et al., 2013). In particular wetland emissions are about 35 Tg CH4 yr−1 lower due to improved partition wetlands and other inland waters. Emissions from geological sources and wild animals are also found to be smaller by 7 Tg CH4 yr−1 by 8 Tg CH4 yr−1, respectively. However, the overall discrepancy between bottom-up and top-down estimates has been reduced by only 5 % compared to Saunois et al. (2016), due to a higher estimate of emissions from inland waters, highlighting the need for more detailed research on emissions factors. Priorities for improving the methane budget include (i) a global, high-resolution map of water-saturated soils and inundated areas emitting methane based on a robust classification of different types of emitting habitats; (ii) further development of process-based models for inland-water emissions; (iii) intensification of methane observations at local scales (e.g., FLUXNET-CH4 measurements) and urban-scale monitoring to constrain bottom-up land surface models, and at regional scales (surface networks and satellites) to constrain atmospheric inversions; (iv) improvements of transport models and the representation of photochemical sinks in top-down inversions; and (v) development of a 3D variational inversion system using isotopic and/or co-emitted species such as ethane to improve source partitioning. The data presented here can be downloaded from https://doi.org/10.18160/GCP-CH4-2019 (Saunois et al., 2020) and from the Global Carbon Project.

[1] Julie Meyer. Food and Agriculture Organization of the United Nations (FAO) , 2021, Yearbook of the United Nations 1984.

[2] Shamil Maksyutov,et al. Technical note: A high-resolution inverse modelling technique for estimating surface CO2 fluxes based on the NIES-TM–FLEXPART coupled transport model and its adjoint , 2021 .

[3] Keywan Riahi,et al. The emissions gap , 2010, Emissions Gap Report 2020.

[4] C. Prigent,et al. Development of a global dataset of Wetland Area and Dynamics for Methane Modeling (WAD2M) , 2020 .

[5] J. Canadell,et al. Increasing anthropogenic methane emissions arise equally from agricultural and fossil fuel sources , 2020, Environmental Research Letters.

[6] M. Evans,et al. Global methane emissions from coal mining to continue growing even with declining coal production. , 2020, Journal of cleaner production.

[7] V. Brovkin,et al. Terrestrial methane emissions from the Last Glacial Maximum to the preindustrial period , 2020, Climate of the Past.

[8] Shamil Maksyutov,et al. Technical note: A high-resolution inverse modelling technique for estimating surface CO2 fluxes based on the NIES-TM – FLEXPART coupled transport model and its adjoint , 2020 .

[9] M. Lewan. Comment on Ideas and perspectives: is shale gas a major driver of recent increase in global atmospheric methane? by Robert W. Howarth (2019) , 2020 .

[10] J. Canadell,et al. Influences of hydroxyl radicals (OH) on top-down estimates of the global and regional methane budgets , 2020, Atmospheric Chemistry and Physics.

[11] P. Bousquet,et al. Satellite‐Derived Global Surface Water Extent and Dynamics Over the Last 25 Years (GIEMS‐2) , 2020, Journal of Geophysical Research: Atmospheres.

[12] R. Weiss,et al. Preindustrial 14CH4 indicates greater anthropogenic fossil CH4 emissions , 2020, Nature.

[13] P. Crill,et al. Shipborne eddy covariance observations of methane fluxes constrain Arctic sea emissions , 2020, Science Advances.

[14] J. Canadell,et al. Regional trends and drivers of the 2000-2017 global methane budget , 2020 .

[15] R. Gautam,et al. Satellite observations reveal extreme methane leakage from a natural gas well blowout , 2019, Proceedings of the National Academy of Sciences.

[16] R. Jackson,et al. Advancing Scientific Understanding of the Global Methane Budget in Support of the Paris Agreement , 2019, Global Biogeochemical Cycles.

[17] W. Oechel,et al. FLUXNET-CH4 Synthesis Activity : Objectives, Observations, and Future Directions , 2019 .

[18] D. Hauglustaine,et al. Impact of atomic chlorine on the modelling of total methane and its 13C : 12C isotopic ratio at global scale , 2019 .

[19] Johannes W. Kaiser,et al. Methane Emission Estimates by the Global High-Resolution Inverse Model Using National Inventories , 2019, Remote. Sens..

[20] Thomas S. Weber,et al. Global ocean methane emissions dominated by shallow coastal waters , 2019, Nature Communications.

[21] V. Brovkin,et al. Terrestrial methane emissions from Last Glacial Maximum to preindustrial , 2019 .

[22] P. Crill,et al. Using ship-borne observations of methane isotopic ratio in the Arctic Ocean to understand methane sources in the Arctic , 2019, Atmospheric Chemistry and Physics.

[23] R. Weiss,et al. Supplementary material to "The Global Methane Budget 2000–2017" , 2019 .

[24] R. Howarth. Ideas and perspectives: is shale gas a major driver of recent increase in global atmospheric methane? , 2019, Biogeosciences.

[25] Andreas Kääb,et al. Northern Hemisphere permafrost map based on TTOP modelling for 2000–2016 at 1 km2 scale , 2019, Earth-Science Reviews.

[26] H. Tian,et al. Revisiting enteric methane emissions from domestic ruminants and their δ13CCH4 source signature , 2019, Nature Communications.

[27] J. Canadell,et al. Inter-model comparison of global hydroxyl radical (OH) distributions and their impact on atmospheric methane over the 2000–2016 period , 2019, Atmospheric Chemistry and Physics.

[28] M. Pihlatie,et al. Methane emissions from tree stems: a new frontier in the global carbon cycle. , 2018, The New phytologist.

[29] D. Jacob,et al. The role of chlorine in global tropospheric chemistry , 2019, Atmospheric Chemistry and Physics.

[30] Dylan B. A. Jones,et al. Emissions of methane in Europe inferred by total column measurements , 2019, Atmospheric Chemistry and Physics.

[31] Katherine Jensen,et al. Surface Water Microwave Product Series Version 3: A Near-Real Time and 25-Year Historical Global Inundated Area Fraction Time Series From Active and Passive Microwave Remote Sensing , 2019, IEEE Geoscience and Remote Sensing Letters.

[32] S. Michel,et al. Very Strong Atmospheric Methane Growth in the 4 Years 2014–2017: Implications for the Paris Agreement , 2019, Global Biogeochemical Cycles.

[33] W. Oechel,et al. Monthly gridded data product of northern wetland methane emissions based on upscaling eddy covariance observations , 2019, Earth System Science Data.

[34] E. Kort,et al. Interpreting contemporary trends in atmospheric methane , 2019, Proceedings of the National Academy of Sciences.

[35] K. Covey,et al. Methane production and emissions in trees and forests. , 2019, The New phytologist.

[36] G. Laruelle,et al. Nitrous oxide emissions from inland waters: Are IPCC estimates too high? , 2018, Global change biology.

[37] H. Tian,et al. Global soil nitrous oxide emissions since the preindustrial era estimated by an ensemble of terrestrial biosphere models: Magnitude, attribution, and uncertainty , 2018, Global change biology.

[38] P. Macreadie,et al. Punching above their weight: Large release of greenhouse gases from small agricultural dams , 2018, Global change biology.

[39] J. Downing,et al. Greenhouse gas emissions from lakes and impoundments: Upscaling in the face of global change , 2018, Limnology and oceanography letters.

[40] Peter Bergamaschi,et al. EDGAR v4.3.2 Global Atlas of the three major greenhouse gas emissions for the period 1970–2012 , 2017, Earth System Science Data.

[41] F. Tubiello. Greenhouse Gas Emissions Due to Agriculture , 2019, Encyclopedia of Food Security and Sustainability.

[42] Icos Ri. ICOS Atmospheric Greenhouse Gas Mole Fractions of CO2, CH4, CO, 14CO2 and Meteorological Observations September 2015 - April 2019 for 19 stations (49 vertical levels), final quality controlled Level 2 data , 2019 .

[43] G. Etiope,et al. Global geological methane emissions: An update of top-down and bottom-up estimates , 2019, Elementa: Science of the Anthropocene.

[44] R. Parker,et al. Attribution of recent increases in atmospheric methane through 3-D inverse modelling , 2018, Atmospheric Chemistry and Physics.

[45] K. Calvin,et al. Global emissions pathways under different socioeconomic scenarios for use in CMIP6: a dataset of harmonized emissions trajectories through the end of the century , 2018, Geoscientific Model Development.

[46] P. Ciais,et al. On the Role of the Flaming to Smoldering Transition in the Seasonal Cycle of African Fire Emissions , 2018, Geophysical Research Letters.

[47] C. Bacour,et al. Error Budget of the MEthane Remote LIdar missioN and Its Impact on the Uncertainties of the Global Methane Budget , 2018, Journal of Geophysical Research: Atmospheres.

[48] G. Etiope,et al. Gridded maps of geological methane emissions and their isotopic signature , 2018, Earth System Science Data.

[49] A. Turner,et al. Modulation of hydroxyl variability by ENSO in the absence of external forcing , 2018, Proceedings of the National Academy of Sciences.

[50] L. Höglund-Isaksson,et al. Carbon in global waste and wastewater flows – its potential as energy source under alternative future waste management regimes , 2018, Advances in Geosciences.

[51] P. Groffman,et al. Declines in methane uptake in forest soils , 2018, Proceedings of the National Academy of Sciences.

[52] P. Patra,et al. Improved Chemical Tracer Simulation by MIROC4.0-based Atmospheric Chemistry-Transport Model (MIROC4-ACTM) , 2018 .

[53] P. Jöckel,et al. A very limited role of tropospheric chlorine as a sink of the greenhouse gas methane , 2018, Atmospheric Chemistry and Physics.

[54] M. Dunbabin,et al. The importance of small artificial water bodies as sources of methane emissions in Queensland, Australia , 2018, Hydrology and Earth System Sciences.

[55] M. Omara,et al. Assessment of methane emissions from the U.S. oil and gas supply chain , 2018, Science.

[56] B. Eyre,et al. Methane emissions partially offset “blue carbon” burial in mangroves , 2018, Science Advances.

[57] Wouter Peters,et al. A UAV-based active AirCore system for measurements of greenhouse gases , 2018 .

[58] Haili Hu,et al. Toward Global Mapping of Methane With TROPOMI: First Results and Intersatellite Comparison to GOSAT , 2018 .

[59] B. Poulter,et al. Spatially Resolved Isotopic Source Signatures of Wetland Methane Emissions , 2018 .

[60] F. Murguia-Flores,et al. Soil Methanotrophy Model (MeMo v1.0): a process-based model to quantify global uptake of atmospheric methane by soil , 2017, Geoscientific Model Development.

[61] V. Arora,et al. An assessment of natural methane fluxes simulated by the CLASS-CTEM model , 2017, Biogeosciences.

[62] P. Ciais,et al. Atmospheric monitoring and inverse modelling for verification of greenhouse gas inventories , 2018 .

[63] S. Pandey,et al. Reduced biomass burning emissions reconcile conflicting estimates of the post-2006 atmospheric methane budget , 2017, Nature Communications.

[64] Luana S. Basso,et al. Large emissions from floodplain trees close the Amazon methane budget , 2017, Nature.

[65] John Robinson,et al. The Total Carbon Column Observing Network site description for Lauder, New Zealand , 2017 .

[66] Merritt N. Deeter,et al. Rapid decline in carbon monoxide emissions and export from East Asia between years 2005 and 2016 , 2017 .

[67] Christopher S. Miller,et al. Methanogenesis in oxygenated soils is a substantial fraction of wetland methane emissions , 2017, Nature Communications.

[68] C. Duarte,et al. Methane Production by Seagrass Ecosystems in the Red Sea , 2017, Front. Mar. Sci..

[69] Lianhai Wu,et al. Higher yields and lower methane emissions with new rice cultivars , 2017, Global change biology.

[70] Jinwei Dong,et al. A global moderate resolution dataset of gross primary production of vegetation for 2000–2016 , 2017, Scientific Data.

[71] P. Salameh,et al. Greenhouse gas measurements from a UK network of tall towers: technical description and first results , 2017 .

[72] Jeffrey L. Anderson,et al. Chemical Feedback From Decreasing Carbon Monoxide Emissions , 2017 .

[73] Martin Wirth,et al. MERLIN: A French-German Space Lidar Mission Dedicated to Atmospheric Methane , 2017, Remote. Sens..

[74] H. Tian,et al. Methane emission from global livestock sector during 1890–2014: Magnitude, trends and spatiotemporal patterns , 2017, Global change biology.

[75] J. Randerson,et al. Global fire emissions estimates during 1997–2016 , 2017 .

[76] Johannes W. Kaiser,et al. Historic global biomass burning emissions for CMIP6 (BB4CMIP) based on merging satellite observations with proxies and fire models (1750-2015) , 2017 .

[77] E. Young,et al. A model for 12CH2D2 and 13CH3D as complementary tracers for the budget of atmospheric CH4 , 2017 .

[78] Martin Herold,et al. An expert system model for mapping tropical wetlands and peatlands reveals South America as the largest contributor , 2017, Global change biology.

[79] R. Weiss,et al. Minimal geological methane emissions during the Younger Dryas–Preboreal abrupt warming event , 2017, Nature.

[80] S. Dhomse,et al. Ozone sensitivity to varying greenhouse gases and ozone-depleting substances in CCMI-1 simulations , 2017 .

[81] Jens Mühle,et al. Role of atmospheric oxidation in recent methane growth , 2017, Proceedings of the National Academy of Sciences.

[82] Christian Frankenberg,et al. Ambiguity in the causes for decadal trends in atmospheric methane and hydroxyl , 2017, Proceedings of the National Academy of Sciences.

[83] Samuel Hammer,et al. Inverse modelling of European CH4 emissions during 2006–2012 using different inverse models and reassessed atmospheric observations , 2017 .

[84] S. Houweling,et al. Global methane emission estimates for 2000–2012 from CarbonTracker Europe-CH4 v1.0 , 2017 .

[85] Meng Li,et al. Historical (1750–2014) anthropogenic emissions of reactive gases and aerosols from the Community Emissions Data System (CEDS) , 2017 .

[86] Shamil Maksyutov,et al. Variability and quasi-decadal changes in the methane budget over the period 2000–2012 , 2017, Atmospheric Chemistry and Physics.

[87] John Robinson,et al. The recent increase of atmospheric methane from 10 years of ground-based NDACC FTIR observations since 2005 , 2017 .

[88] Andrea Stenke,et al. Review of the global models used within phase 1 of the Chemistry–Climate Model Initiative (CCMI) , 2017 .

[89] F. Pérez-Barbería. Scaling methane emissions in ruminants and global estimates in wild populations. , 2017, The Science of the total environment.

[90] J. Megonigal,et al. Temperate forest methane sink diminished by tree emissions. , 2015, The New phytologist.

[91] S. Saatchi,et al. Greenhouse gas emissions intensity of global croplands , 2017 .

[92] J. Eom,et al. The Shared Socioeconomic Pathways and their energy, land use, and greenhouse gas emissions implications: An overview , 2017 .

[93] V. Brovkin,et al. Global wetland contribution to 2000–2012 atmospheric methane growth rate dynamics , 2017 .

[94] Lena Höglund-Isaksson,et al. Bottom-up simulations of methane and ethane emissions from global oil and gas systems 1980 to 2012 , 2017 .

[95] G. Myhre,et al. Radiative forcing of carbon dioxide, methane, and nitrous oxide: A significant revision of the methane radiative forcing , 2016 .

[96] Patrick M. Crill,et al. Double‐counting challenges the accuracy of high‐latitude methane inventories , 2016 .

[97] M. Chipperfield,et al. A global model of tropospheric chlorine chemistry: Organic versus inorganic sources and impact on methane oxidation , 2016 .

[98] B. Lehner,et al. Estimating the volume and age of water stored in global lakes using a geo-statistical approach , 2016, Nature Communications.

[99] J. Canadell,et al. The global methane budget 2000-2012. What's next? , 2016 .

[100] Peter Bergamaschi,et al. U.S. CH4 emissions from oil and gas production: Have recent large increases been detected? , 2016 .

[101] E. Delong,et al. Marine methane paradox explained by bacterial degradation of dissolved organic matter , 2016 .

[102] J. Pekel,et al. High-resolution mapping of global surface water and its long-term changes , 2016, Nature.

[103] Philippe Ciais,et al. Inventory of anthropogenic methane emissions in mainland China from 1980 to 2010 , 2016 .

[104] Geoffrey C. Toon,et al. Quantifying the loss of processed natural gas within California's South Coast Air Basin using long-term measurements of ethane and methane , 2016 .

[105] A. Ito,et al. A 4D-Var inversion system based on the icosahedral grid model (NICAM-TM 4D-Var v1.0) – Part 2: Optimization scheme and identical twin experiment of atmospheric CO 2 inversion , 2016 .

[106] T. Treude,et al. Effects of climate change on methane emissions from seafloor sediments in the Arctic Ocean: A review , 2016 .

[107] N. Barros,et al. Greenhouse Gas Emissions from Reservoir Water Surfaces: A New Global Synthesis. , 2016, Bioscience.

[108] P. Crill,et al. Spatio‐temporal variability of lake CH4 fluxes and its influence on annual whole lake emission estimates , 2016 .

[109] C. Frankenberg,et al. Inverse modeling of pan-Arctic methane emissions at high spatial resolution:what can we learn from assimilating satellite retrievals and using differentprocess-based wetland and lake biogeochemical models? , 2016 .

[110] Y. Niwa,et al. A 4D-Var inversion system based on the icosahedral grid model (NICAM-TM 4D-Var v1.0) - Part 1: Offline forward and adjoint transport models , 2016 .

[111] Pieter P. Tans,et al. Upward revision of global fossil fuel methane emissions based on isotope database , 2016, Nature.

[112] J. Lelieveld,et al. Global tropospheric hydroxyl distribution, budget and reactivity , 2016 .

[113] R. Thompson,et al. Methane fluxes in the high northern latitudes for 2005–2013 estimated using a Bayesian atmospheric inversion , 2016 .

[114] Shamil Maksyutov,et al. Inter-annual variability of summertime CO2 exchange in Northern Eurasia inferred from GOSAT XCO2 , 2016 .

[115] Brian C. O'Neill,et al. The Scenario Model Intercomparison Project (ScenarioMIP) for CMIP6 , 2016 .

[116] C. Sweeney,et al. AirCore-HR: a high-resolution column sampling to enhance the vertical description of CH 4 and CO 2 , 2016 .

[117] W. Oechel,et al. A multi-scale comparison of modeled and observed seasonal methane emissions in northern wetlands , 2016 .

[118] Hanqin Tian,et al. Methane emissions from global rice fields: Magnitude, spatiotemporal patterns, and environmental controls , 2016 .

[119] Philippe Bousquet,et al. Rising atmospheric methane: 2007–2014 growth and isotopic shift , 2016 .

[120] Tatsuya Yokota,et al. Bias corrections of GOSAT SWIR XCO2 and XCH4 with TCCON data and their evaluation using aircraft measurement data , 2016 .

[121] Corinne Le Quéré,et al. Role of zooplankton dynamics for Southern Ocean phytoplankton biomass and global biogeochemical cycles , 2016 .

[122] Thomas Kaminski,et al. Global inverse modeling of CH4 sources and sinks: An overview of methods , 2016 .

[123] Qiang Yu,et al. Methane emissions from the trunks of living trees on upland soils. , 2016, The New phytologist.

[124] D. Labat,et al. Effect of sporadic destratification, seasonal overturn, and artificial mixing on CH 4 emissions from a subtropical hydroelectric reservoir , 2016 .

[125] P. Crill,et al. Methane fluxes from the sea to the atmosphere across the Siberian shelf seas , 2016 .

[126] F. Keppler,et al. Evidence for methane production by the marine algae Emiliania huxleyi , 2016 .

[127] Samuel T. Christel,et al. The ecology of methane in streams and rivers: patterns, controls, and global significance , 2016 .

[128] Ilse Aben,et al. Inverse modeling of GOSAT-retrieved ratios of total column CH4 and CO2 for 2009 and 2010 , 2016 .

[129] S. Michel,et al. A 21st-century shift from fossil-fuel to biogenic methane emissions indicated by 13CH4 , 2016, Science.

[130] T. Crowther,et al. Greenhouse trace gases in deadwood , 2016, Biogeochemistry.

[131] P. Tans,et al. Characteristics of atmospheric CO2 and CH4 at the Shangdianzi regional background station in China , 2016 .

[132] T. Laurila,et al. Large contribution of boreal upland forest soils to a catchment‐scale CH4 balance in a wet year , 2016 .

[133] J. Peischl,et al. Methane emissions from the 2015 Aliso Canyon blowout in Los Angeles, CA , 2016, Science.

[134] Eric A. Kort,et al. Regional Methane Emission Estimation Based on Observed Atmospheric Concentrations (2002-2012) , 2016 .

[135] Pierre Friedlingstein,et al. The terrestrial biosphere as a net source of greenhouse gases to the atmosphere , 2016, Nature.

[136] P. Raymond,et al. Large contribution to inland water CO2 and CH4 emissions from very small ponds , 2016 .

[137] P. Crill,et al. Biased sampling of methane release from northern lakes: A problem for extrapolation , 2016 .

[138] David Bastviken,et al. Climate-sensitive northern lakes and ponds are critical components of methane release , 2016 .

[139] L. Bian,et al. CH4 Monitoring and Background Concentration at Zhongshan Station, Antarctica , 2016 .

[140] Manuela Herman,et al. Aeronomy Of The Middle Atmosphere , 2016 .

[141] J. Chanton,et al. Present-day permafrost carbon feedback from thermokarst lakes , 2016 .

[142] Mikhail Zhizhin,et al. Methods for Global Survey of Natural Gas Flaring from Visible Infrared Imaging Radiometer Suite Data , 2015 .

[143] Anna Liljedahl,et al. Cold season emissions dominate the Arctic tundra methane budget , 2015, Proceedings of the National Academy of Sciences.

[144] R. Sussmann,et al. Contribution of oil and natural gas production to renewed increase in atmospheric methane (2007–2014): top–down estimate from ethane and methane column observations , 2015 .

[145] Daniel C. Anderson,et al. Quantifying the causes of differences in tropospheric OH within global models , 2015 .

[146] Kyle McDonald,et al. Development and Evaluation of a Multi-Year Fractional Surface Water Data Set Derived from Active/Passive Microwave Remote Sensing Data , 2015, Remote. Sens..

[147] Anthony J. Marchese,et al. Reconciling divergent estimates of oil and gas methane emissions , 2015, Proceedings of the National Academy of Sciences.

[148] P. Ciais,et al. Decadal trends in global CO emissions as seen by MOPITT , 2015 .

[149] M. Santini,et al. Changes in the world rivers’ discharge projected from an updated high resolution dataset of current and future climate zones , 2015 .

[150] Q. Zhuang,et al. Methane emissions from pan‐Arctic lakes during the 21st century: An analysis with process‐based models of lake evolution and biogeochemistry , 2015 .

[151] B. Poulter,et al. Modeling spatiotemporal dynamics of global wetlands: comprehensive evaluation of a new sub-grid TOPMODEL parameterization and uncertainties , 2015 .

[152] G. Dieckmann,et al. Methane excess in Arctic surface water- triggered by sea ice formation and melting , 2015, Scientific Reports.

[153] Ray F. Weiss,et al. Atmospheric methane evolution the last 40 years , 2015 .

[154] Birgit Heim,et al. A novel approach for the characterization of tundra wetland regions with C-band SAR satellite data , 2015, International journal of remote sensing.

[155] S. Joye,et al. The East Siberian Arctic Shelf: towards further assessment of permafrost-related methane fluxes and role of sea ice , 2015, Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences.

[156] Thomas Dubos,et al. DYNAMICO-1.0, an icosahedral hydrostatic dynamical core designed for consistency and versatility , 2015 .

[157] E. Dlugokencky,et al. Atmospheric constraints on the methane emissions from the East Siberian Shelf , 2015 .

[158] F. Tubiello,et al. New estimates of CO2 forest emissions and removals: 1990-2015 , 2015 .

[159] Philippe Bousquet,et al. Sensitivity of the recent methane budget to LMDz sub-grid-scale physical parameterizations , 2015 .

[160] P. Ciais,et al. Long-lived atmospheric trace gases measurements in flask samples from three stations in India , 2015 .

[161] R. Koster,et al. The Quick Fire Emissions Dataset (QFED): Documentation of Versions 2.1, 2.2 and 2.4. Volume 38; Technical Report Series on Global Modeling and Data Assimilation , 2015 .

[162] P. Ciais,et al. Reduced carbon emission estimates from fossil fuel combustion and cement production in China , 2015, Nature.

[163] S. Pandey,et al. On the use of satellite-derived CH 4 : CO 2 columns in a joint inversion of CH 4 and CO 2 fluxes , 2015 .

[164] C. Peng,et al. A novel pathway of direct methane production and emission by eukaryotes including plants, animals and fungi: An overview , 2015 .

[165] Hong Jiang,et al. Estimating global natural wetland methane emissions using process modelling: spatio-temporal patterns and contributions to atmospheric methane fluctuations , 2015 .

[166] A. Borges,et al. Globally significant greenhouse-gas emissions from African inland waters , 2015 .

[167] Kostas Tsigaridis,et al. Interannual variability of tropospheric trace gases and aerosols: The role of biomass burning emissions , 2015 .

[168] H. Eskes,et al. A tropospheric chemistry reanalysis for the years 2005–2012 based on an assimilation of OMI, MLS, TES, and MOPITT satellite data , 2015 .

[169] Charlotte Scheutz,et al. Methane emission estimates using chamber and tracer release experiments for a municipal waste water treatment plant , 2015 .

[170] M. Alawi,et al. Environmental factors affecting methane distribution and bacterial methane oxidation in the German Bight (North Sea) , 2015 .

[171] E. Hornibrook,et al. The contribution of trees to ecosystem methane emissions in a temperate forested wetland , 2015, Global change biology.

[172] Joe R. Melton,et al. Competition between plant functional types in the Canadian Terrestrial Ecosystem Model (CTEM) v. 2.0 , 2015 .

[173] P. M. Lang,et al. Seasonal climatology of CO2 across North America from aircraft measurements in the NOAA/ESRL Global Greenhouse Gas Reference Network , 2015 .

[174] Ronald G. Prinn,et al. Methane emissions in East Asia for 2000–2011 estimated using an atmospheric Bayesian inversion , 2015 .

[175] A. Biastoch,et al. Modeling the fate of methane hydrates under global warming , 2015 .

[176] C. Knoblauch,et al. Methane oxidation following submarine permafrost degradation: Measurements from a central Laptev Sea shelf borehole , 2015 .

[177] R. Weiss,et al. Role of OH variability in the stalling of the global atmospheric CH4 growth rate from 1999 to 2006 , 2015 .

[178] Touché Howard,et al. Direct measurements show decreasing methane emissions from natural gas local distribution systems in the United States. , 2015, Environmental science & technology.

[179] Jeff Peischl,et al. Quantifying atmospheric methane emissions from the Haynesville, Fayetteville, and northeastern Marcellus shale gas production regions , 2015 .

[180] G. Etiope. Natural Gas Seepage: The Earth’s Hydrocarbon Degassing , 2015 .

[181] Hanqin Tian,et al. Global methane and nitrous oxide emissions from terrestrial ecosystems due to multiple environmental changes , 2015 .

[182] G. Rhoderick,et al. Methane standards made in whole and synthetic air compared by cavity ring down spectroscopy and gas chromatography with flame ionization detection for atmospheric monitoring applications. , 2015, Analytical chemistry.

[183] H. Tian,et al. Landscape-level terrestrial methane flux observed from a very tall tower , 2015 .

[184] Jed O. Kaplan,et al. WETCHIMP-WSL: intercomparison of wetland methane emissions models over West Siberia , 2015 .

[185] C. Flachsland. Mitigation of Climate Change: Contribution of Working Group III to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change , 2015 .

[186] Keith A. Smith,et al. Emission of methane, carbon monoxide, carbon dioxide and short‐chain hydrocarbons from vegetation foliage under ultraviolet irradiation , 2015, Plant, cell & environment.

[187] Mark S. Zahniser,et al. Methane emissions from natural gas infrastructure and use in the urban region of Boston, Massachusetts , 2015, Proceedings of the National Academy of Sciences.

[188] Hans-Peter Grossart,et al. Enhancing surface methane fluxes from an oligotrophic lake: exploring the microbubble hypothesis. , 2015, Environmental science & technology.

[189] D. M. Lawrence,et al. Climate change and the permafrost carbon feedback , 2014, Nature.

[190] Arctic Monitoring,et al. AMAP Assessment 2015: Methane as an Arctic climate forcer. , 2015 .

[191] F. Keppler,et al. Evidence for methane production by marine algae , 2015 .

[192] Sandro Federici,et al. New estimates of CO 2 forest emissions and removals : 1990 – 2015 q , 2015 .

[193] T. Christensen,et al. Natural Terrestrial methane sources in the Arctic , 2015 .

[194] G. Janssens‑Maenhout,et al. Anthropogenic methane sources, emissions and future projections , 2015 .

[195] J. Greet,et al. Part III: Total greenhouse gas emissions , 2015 .

[196] F. Siegert,et al. Biomass burning fuel consumption rates: a field measurement database , 2014 .

[197] F. Joos,et al. DYPTOP: a cost-efficient TOPMODEL implementation to simulate sub-grid spatio-temporal dynamics of global wetlands and peatlands , 2014 .

[198] O. Schneising,et al. Comparison of the HadGEM2 climate-chemistry model against in situ and SCIAMACHY atmospheric methane data , 2014 .

[199] G. Q. Chen,et al. China's CH4 and CO2 emissions: Bottom-up estimation and comparative analysis , 2014 .

[200] Guido Grosse,et al. Estimated stocks of circumpolar permafrost carbon with quantified uncertainty ranges and identified data gaps , 2014 .

[201] K. Caldeira,et al. Key factors for assessing climate benefits of natural gas versus coal electricity generation , 2014 .

[202] Colm Sweeney,et al. Methane emissions from Alaska in 2012 from CARVE airborne observations , 2014, Proceedings of the National Academy of Sciences.

[203] E. Stanley,et al. Ebullitive methane emissions from oxygenated wetland streams , 2014, Global change biology.

[204] Patrick M. Crill,et al. Methane dynamics regulated by microbial community response to permafrost thaw , 2014, Nature.

[205] R. Jackson,et al. The Environmental Costs and Benefits of Fracking , 2014 .

[206] D. Griffith,et al. Retrieval of tropospheric column-averaged CH4 mole fraction by solar absorption FTIR-spectrometry using N2O as a proxy , 2014 .

[207] J. Urban,et al. Vertical structure of stratospheric water vapour trends derived from merged satellite data. , 2014, Nature geoscience.

[208] O. Schneising,et al. Remote sensing of fugitive methane emissions from oil and gas production in North American tight geologic formations , 2014 .

[209] C. Verpoorter,et al. A global inventory of lakes based on high‐resolution satellite imagery , 2014 .

[210] R. Weiss,et al. Observational evidence for interhemispheric hydroxyl-radical parity , 2014, Nature.

[211] D. Wunch,et al. Derivation of tropospheric methane from TCCON CH 4 and HF total column observations , 2014 .

[212] D. Bastviken,et al. Methane emissions from Amazonian Rivers and their contribution to the global methane budget , 2014, Global change biology.

[213] S. O'Doherty,et al. Comparisons of continuous atmospheric CH4, CO2 and N2O measurements - results from a travelling instrument campaign at Mace Head , 2014 .

[214] Colm Sweeney,et al. CarbonTracker-CH 4 : an assimilation system for estimating emissions of atmospheric methane , 2014 .

[215] Jeffrey R. White,et al. A synthesis of methane emissions from 71 northern, temperate, and subtropical wetlands , 2014, Global change biology.

[216] J. M. Eiler,et al. Formation temperatures of thermogenic and biogenic methane , 2014, Science.

[217] Gabrielle Pétron,et al. A new look at methane and nonmethane hydrocarbon emissions from oil and natural gas operations in the Colorado Denver‐Julesburg Basin , 2014 .

[218] Changhui Peng,et al. Modelling methane emissions from natural wetlands by development and application of the TRIPLEX-GHG model , 2014 .

[219] Hartmut Boesch,et al. Inverse modelling of CH 4 emissions for 2010–2011 using different satellite retrieval products from GOSAT and SCIAMACHY , 2014 .

[220] Edward V. Browell,et al. Performance simulations for a spaceborne methane lidar mission , 2014 .

[221] Robert W Howarth,et al. Toward a better understanding and quantification of methane emissions from shale gas development , 2014, Proceedings of the National Academy of Sciences.

[222] O. A. Castelán-Ortega,et al. Modeling methane emissions and methane inventories for cattle production systems in Mexico , 2014 .

[223] P. Giorgio,et al. Patterns in CH4 and CO2 concentrations across boreal rivers: Major drivers and implications for fluvial greenhouse emissions under climate change scenarios , 2014, Global change biology.

[224] Sander Houweling,et al. Methane emissions from floodplains in the Amazon Basin: challenges in developing a process-based model for global applications , 2014 .

[225] Barbara Zielinska,et al. Air impacts of increased natural gas acquisition, processing, and use: a critical review. , 2014, Environmental science & technology.

[226] Diana R. Nemergut,et al. Palm oil wastewater methane emissions and bioenergy potential , 2014 .

[227] E. Kort,et al. Methane Leaks from North American Natural Gas Systems , 2014, Science.

[228] Luana S. Basso,et al. Drought sensitivity of Amazonian carbon balance revealed by atmospheric measurements , 2014, Nature.

[229] Philippe Bousquet,et al. Methane on the Rise—Again , 2014, Science.

[230] P. Crill,et al. Energy input is primary controller of methane bubbling in subarctic lakes , 2014 .

[231] Dario Papale,et al. A full greenhouse gases budget of Africa: synthesis, uncertainties, and vulnerabilities , 2014 .

[232] Charles W Cook,et al. Natural gas pipeline leaks across Washington, DC. , 2014, Environmental science & technology.

[233] P. Patra,et al. Variations of tropospheric methane over Japan during 1988–2010 , 2014 .

[234] D. Shindell,et al. Anthropogenic and Natural Radiative Forcing , 2014 .

[235] J. André,et al. Le méthane : d'où vient-il et quel son impact sur le climat ? , 2014 .

[236] C. Stubbs,et al. Ebullition and storm-induced methane release from the East Siberian Arctic Shelf , 2014 .

[237] Corinne Le Quéré,et al. Carbon and Other Biogeochemical Cycles , 2014 .

[238] M. Obersteiner,et al. Biomass use, production, feed efficiencies, and greenhouse gas emissions from global livestock systems , 2013, Proceedings of the National Academy of Sciences.

[239] B. Mijling,et al. Atmospheric Chemistry and Physics Regional Nitrogen Oxides Emission Trends in East Asia Observed from Space , 2022 .

[240] Philippe Bousquet,et al. Stable atmospheric methane in the 2000s: key-role of emissions from natural wetlands , 2013 .

[241] Wataru Takeuchi,et al. Methane concentrations over Monsoon Asia as observed by SCIAMACHY: Signals of methane emission from rice cultivation , 2013 .

[242] Scot M. Miller,et al. Anthropogenic emissions of methane in the United States , 2013, Proceedings of the National Academy of Sciences.

[243] P. Ciais,et al. Global carbon dioxide emissions from inland waters , 2013, Nature.

[244] B. Khattatov,et al. Estimation of global CO2 fluxes using ground-based and satellite (GOSAT) observation data with empirical orthogonal functions , 2013 .

[245] J. Thornton,et al. An MCM modeling study of nitryl chloride (ClNO 2 ) impacts on oxidation, ozone production and nitrogen oxide partitioning in polluted continental outflow , 2013 .

[246] Peter Bergamaschi,et al. A multi-year methane inversion using SCIAMACHY, accounting for systematic errors using TCCON measurements , 2013 .

[247] Ilse Aben,et al. Comparison of CH4 inversions based on 15 months of GOSAT and SCIAMACHY observations , 2013 .

[248] Hartmut Boesch,et al. The greenhouse gas climate change initiative (GHG-CCI): Comparative validation of GHG-CCI SCIAMACHY/ENVISAT and TANSO-FTS/GOSAT CO2 and CH4 retrieval algorithm products with measurements from the TCCON , 2013 .

[249] Peter Bergamaschi,et al. Three decades of global methane sources and sinks , 2013 .

[250] James Thomas,et al. Measurements of methane emissions at natural gas production sites in the United States , 2013, Proceedings of the National Academy of Sciences.

[251] E. Saikawa,et al. Response of global soil consumption of atmospheric methane to changes in atmospheric climate and nitrogen deposition , 2013 .

[252] Gabrielle Pétron,et al. Methane emissions estimate from airborne measurements over a western United States natural gas field , 2013 .

[253] Shamil Maksyutov,et al. Temporal changes in the emissions of CH 4 and CO from China estimated from CH 4 / CO 2 and CO / CO 2 correlations observed at Hateruma Island , 2013 .

[254] G. Faluvegi,et al. Direct top‐down estimates of biomass burning CO emissions using TES and MOPITT versus bottom‐up GFED inventory , 2013 .

[255] Peter Bergamaschi,et al. Atmospheric CH4 in the first decade of the 21st century: Inverse modeling analysis using SCIAMACHY satellite retrievals and NOAA surface measurements , 2013 .

[256] Tatsuya Yokota,et al. Improvement of the retrieval algorithm for GOSAT SWIR XCO2 and XCH4 and their validation using TCCON data , 2013 .

[257] Arti Bhatia,et al. Methane and nitrous oxide emissions from Indian rice paddies, agricultural soils and crop residue burning , 2013 .

[258] Qianlai Zhuang,et al. Methane emissions from wetlands: biogeochemical, microbial, and modeling perspectives from local to global scales , 2013, Global change biology.

[259] F. Joos,et al. Impact of an abrupt cooling event on interglacial methane emissions in northern peatlands , 2013 .

[260] J. Randerson,et al. Analysis of daily, monthly, and annual burned area using the fourth‐generation global fire emissions database (GFED4) , 2013 .

[261] Philippe Bousquet,et al. On the consistency between global and regional methane emissions inferred from SCIAMACHY, TANSO-FTS, IASI and surface measurements , 2013 .

[262] B. Hungate,et al. Increased greenhouse-gas intensity of rice production under future atmospheric conditions , 2013 .

[263] Pete Smith,et al. The FAOSTAT database of greenhouse gas emissions from agriculture , 2013 .

[264] Kaiguang Zhao,et al. Mapping urban pipeline leaks: methane leaks across Boston. , 2013, Environmental pollution.

[265] Yan Bai,et al. Areas of the global major river plumes , 2013, Acta Oceanologica Sinica.

[266] C. Peng,et al. Methane emissions from rice paddies natural wetlands, lakes in China: synthesis new estimate , 2013, Global change biology.

[267] Adriana Gamazo,et al. EURYDICE (2013): Key data on teachers and school leaders in Europe. 2013 edition Eurydice report (Luxembourg Publications Office of the European Union) , 2013 .

[268] Shamil Maksyutov,et al. Inverse Modeling of CO2 Fluxes Using GOSAT Data and Multi-Year Ground-Based Observations , 2013 .

[269] E. Hornibrook,et al. Trees are major conduits for methane egress from tropical forested wetlands. , 2013, The New phytologist.

[270] C. Tebaldi,et al. Long-term Climate Change: Projections, Commitments and Irreversibility , 2013 .

[271] Catherine Prigent,et al. Present state of global wetland extent and wetland methane modelling: methodology of a model inter-comparison project (WETCHIMP) , 2012 .

[272] R. Weiss,et al. Estimating regional methane surface fluxes: the relative importance of surface and GOSAT mole fraction measurements , 2012 .

[273] J. Randerson,et al. Global burned area and biomass burning emissions from small fires , 2012 .

[274] T. Machida,et al. Contributions of natural and anthropogenic sources to atmospheric methane variations over western Siberia estimated from its carbon and hydrogen isotopes , 2012 .

[275] D. Lawrence,et al. Diagnosing Present and Future Permafrost from Climate Models , 2012 .

[276] J. Lamarque,et al. Preindustrial to present-day changes in tropospheric hydroxyl radical and methane lifetime from the Atmospheric Chemistry and Climate Model Intercomparison Project (ACCMIP) , 2012 .

[277] Hidekazu Matsueda,et al. Distribution of methane in the tropical upper troposphere measured by CARIBIC and CONTRAIL aircraft , 2012 .

[278] Rodel D. Lasco,et al. The carbon budget of South Asia , 2012 .

[279] L. Höglund-Isaksson. Global anthropogenic methane emissions 2005-2030: technical mitigation potentials and costs , 2012 .

[280] J. Hartmann,et al. Global multi-scale segmentation of continental and coastal waters from the watersheds to the continental margins , 2012 .

[281] Veronika Eyring,et al. Analysis of Present Day and Future OH and Methane Lifetime in the ACCMIP Simulations , 2012 .

[282] J. Lamarque,et al. The Atmospheric Chemistry and Climate Model Intercomparison Project (ACCMIP): overview and description of models, simulations and climate diagnostics , 2012 .

[283] Benjamin Poulter,et al. Present state of global wetland extent and wetland methane modelling: conclusions from a model inter-comparison project (WETCHIMP) , 2012 .

[284] Nicola J. Blake,et al. Long-term decline of global atmospheric ethane concentrations and implications for methane , 2012, Nature.

[285] M. Bradford,et al. Elevated methane concentrations in trees of an upland forest , 2012 .

[286] S. Houweling,et al. Methane airborne measurements and comparison to global models during BARCA , 2012 .

[287] Michael J. Prather,et al. Future methane, hydroxyl, and their uncertainties: key climate and emission parameters for future predictions , 2012 .

[288] Christian Hensen,et al. The Global Inventory of Methane Hydrate in Marine Sediments: A Theoretical Approach , 2012 .

[289] R. Prinn,et al. The value of high‐frequency, high‐precision methane isotopologue measurements for source and sink estimation , 2012 .

[290] Brendan G. McKie,et al. Continental-Scale Effects of Nutrient Pollution on Stream Ecosystem Functioning , 2012, Science.

[291] G. Etiope. Climate science: Methane uncovered , 2012 .

[292] H. Tian,et al. Methane exchange between marshland and the atmosphere over China during 1949–2008 , 2012 .

[293] M. Zahniser,et al. Mass fluxes and isofluxes of methane (CH4) at a New Hampshire fen measured by a continuous wave quantum cascade laser spectrometer , 2012 .

[294] Ilse Aben,et al. Methane retrievals from Greenhouse Gases Observing Satellite (GOSAT) shortwave infrared measurements: Performance comparison of proxy and physics retrieval algorithms , 2012 .

[295] A. Ravishankara,et al. Stratospheric ozone depletion due to nitrous oxide: influences of other gases , 2012, Philosophical Transactions of the Royal Society B: Biological Sciences.

[296] Michael J. Prather,et al. Reactive greenhouse gas scenarios: Systematic exploration of uncertainties and the role of atmospheric chemistry , 2012 .

[297] W. Silver,et al. The challenges of measuring methane fluxes and concentrations over a peatland pasture , 2012 .

[298] A. Ito,et al. Use of a process-based model for assessing the methane budgets of global terrestrial ecosystems and evaluation of uncertainty , 2012 .

[299] Kaarle Kupiainen,et al. Simultaneously Mitigating Near-Term Climate Change and Improving Human Health and Food Security , 2012, Science.

[300] L. Cathles,et al. A commentary on “The greenhouse-gas footprint of natural gas in shale formations” by R.W. Howarth, R. Santoro, and Anthony Ingraffea , 2012, Climatic Change.

[301] J. Greet,et al. Trends in global CO2 emissions: 2012 report , 2012 .

[302] Aie. CO2 Emissions from Fuel Combustion 2012 , 2012 .

[303] Janssens-Maenhout Greet,et al. CO2 Emissions from fuel combustion (2012 Edition): Part III: Greenhouse-Gas Emissions , 2012 .

[304] Carlos M. Duarte,et al. A blueprint for blue carbon: toward an improved understanding of the role of vegetated coastal habitats in sequestering CO2 , 2011 .

[305] W. Oechel,et al. An assessment of the carbon balance of Arctic tundra: comparisons among observations, process models, and atmospheric inversions , 2011 .

[306] M. Vrac,et al. Present and LGM permafrost from climate simulations: contribution of statistical downscaling. , 2010 .

[307] A. Stohl,et al. Arctic methane sources: Isotopic evidence for atmospheric inputs , 2011 .

[308] J. Melton,et al. Enrichment in 13 C of atmospheric CH 4 during the Younger Dryas termination , 2011 .

[309] Shamil Maksyutov,et al. Regional methane emission from West Siberia mire landscapes , 2011 .

[310] A. Strunk,et al. The application of the Modified Band Approach for the calculation of on-line photodissociation rate constants in TM5: implications for oxidative capacity , 2011 .

[311] S. Houweling,et al. Interpreting methane variations in the past two decades using measurements of CH 4 mixing ratio and isotopic composition , 2011 .

[312] A. Arneth,et al. Global patterns of land-atmosphere fluxes of carbon dioxide, latent heat, and sensible heat derived from eddy covariance, satellite, and meteorological observations , 2011 .

[313] J. Randerson,et al. Reduced methane growth rate explained by decreased Northern Hemisphere microbial sources , 2011, Nature.

[314] P. Ciais,et al. Climate-CH 4 feedback from wetlands and its interaction with the climate-CO 2 feedback , 2011 .

[315] K. Calvin,et al. The RCP greenhouse gas concentrations and their extensions from 1765 to 2300 , 2011 .

[316] Hartmut Boesch,et al. Methane observations from the Greenhouse Gases Observing SATellite: Comparison to ground‐based TCCON data and model calculations , 2011 .

[317] M. Razinger,et al. Biomass burning emissions estimated with a global fire assimilation system based on observed fire radiative power , 2011 .

[318] W. J. Riley,et al. Barriers to predicting changes in global terrestrial methane fluxes: analyses using CLM4Me, a methane biogeochemistry model integrated in CESM , 2011 .

[319] Akihiko Kuze,et al. Toward accurate CO_2 and CH_4 observations from GOSAT , 2011 .

[320] Akihiko Kuze,et al. Toward accurate CO2 and CH4 observations from GOSAT , 2011 .

[321] Evaluation of methane emissions from West Siberian wetlands based on inverse modeling , 2011 .

[322] Philippe Bousquet,et al. Constraining global methane emissions and uptake by ecosystems , 2011 .

[323] H. Tian,et al. Net exchanges of CO2, CH4, and N2O between China's terrestrial ecosystems and the atmosphere and their contributions to global climate warming , 2011 .

[324] Shamil Maksyutov,et al. TransCom model simulations of CH4 and related species: linking transport, surface flux and chemical loss with CH4 variability in the troposphere and lower stratosphere , 2011 .

[325] E. Dlugokencky,et al. Global atmospheric methane: budget, changes and dangers , 2011, Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences.

[326] S. Wofsy,et al. HIAPER Pole-to-Pole Observations (HIPPO): fine-grained, global-scale measurements of climatically important atmospheric gases and aerosols , 2011, Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences.

[327] Justus Notholt,et al. The Total Carbon Column Observing Network , 2011, Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences.

[328] Victor Brovkin,et al. A dynamic model of wetland extent and peat accumulation: Results for the Holocene , 2011 .

[329] C. Prigent,et al. The El Niño–Southern Oscillation and wetland methane interannual variability , 2011 .

[330] A. Ingraffea,et al. Methane and the greenhouse-gas footprint of natural gas from shale formations , 2011 .

[331] Merritt N. Deeter,et al. Ten years of CO emissions as seen from Measurements of Pollution in the Troposphere (MOPITT) , 2011 .

[332] Peter Bergamaschi,et al. Global column-averaged methane mixing ratios from 2003 to 2009 as derived from SCIAMACHY: Trends and variability , 2011 .

[333] P. Friedlingstein,et al. Late Holocene methane rise caused by orbitally controlled increase in tropical sources , 2011, Nature.

[334] Patrick M. Crill,et al. Freshwater Methane Emissions Offset the Continental Carbon Sink , 2011, Science.

[335] P. Jöckel,et al. Small Interannual Variability of Global Atmospheric Hydroxyl , 2011, Science.

[336] H. Tian,et al. Spatial and temporal patterns of CO2 and CH4 fluxes in China’s croplands in response to multifactor environmental changes , 2011 .

[337] A. Borges,et al. 5.04 – Carbon Dioxide and Methane Dynamics in Estuaries , 2011 .

[338] S. K. Akagi,et al. The Fire INventory from NCAR (FINN): a high resolution global model to estimate the emissions from open burning , 2010 .

[339] Tatsuya Yokota,et al. Preliminary validation of column-averaged volume mixing ratios of carbon dioxide and methane retrieved from GOSAT short-wavelength infrared spectra , 2010 .