The Journal of
the Korean Society on Water Environment

The Journal of
the Korean Society on Water Environment

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  • ISSN : 2289-0971 (Print)
  • ISSN : 2289-098X (Online)
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References

1 
Aben R. C. H., Oliveira Junior E. S., Carlos A. R., van Bergen T. J. H. M., Lamers L. P. M., Kosten S., 2022, Impact of plant species and intense nutrient loading on CH4 and N2O fluxes from small inland waters: An experimental approach, Aquatic Botany, Vol. 180, pp. 103527DOI
2 
Aho K. S., Maavara T., Cawley K. M., Raymond P. A., 2023, Inland waters can act as nitrous oxide sinks: Observation and modeling reveal that nitrous oxide undersaturation may partially offset emissions, Geophysical Research Letters, Vol. 50, pp. e2023GL104987DOI
3 
Amani M., Dufitimana E., Ndagijwenimana E., Kalisa E., 2025, Tropical artificial rural and urban ponds are net sources of carbon dioxide and methane in Rwanda, East Africa, Environmental and Sustainability Indicators, Vol. 27, pp. 100867DOI
4 
Arsenault J., Talbot J., Brown L. E., Holden J., Martinez-Cruz K., Sepulveda-Jauregui A., Swindles G. T., Wauthy M., Lapierre J. F., 2022, Biogeochemical distinctiveness of peatland ponds, thermokarst waterbodies, and lakes, Geophysical Research Letters, Vol. 49, No. 11, pp. e2021GL097492DOI
5 
Baldocchi D. D., 2003, Assessing the eddy covariance technique for evaluating carbon dioxide exchange rates of ecosystems: Past, present and future, Global Change Biology, Vol. 9, No. 4, pp. 479-492DOI
6 
Baldocchi D. D., 2014, Measuring fluxes of trace gases and energy between ecosystems and the atmosphere – The state and future of the eddy covariance method, Global Change Biology, Vol. 20, No. 12, pp. 3600-3609DOI
7 
Barbosa P. M., Melack J. M., Amaral J. H. F., Linkhorst A., Forsberg B. R., 2021, Large seasonal and habitat differences in methane ebullition on the Amazon floodplain, Journal of Geophysical Research: Biogeosciences, Vol. 126, No. 7, pp. e2020JG005911DOI
8 
Bastviken D., Cole J., Pace M., Tranvik L., 2004, Methane emissions from lakes: Dependence of lake characteristics, two regional assessments, and a global estimate, Global Biogeochemical Cycles, Vol. 18, No. 4, pp. GB4009DOI
9 
Bastviken D., Tranvik L. J., Downing J. A., Crill P. M., Enrich-Prast A., 2011, Freshwater methane emissions offset the continental carbon sink, Science, Vol. 331, No. 6013, pp. 50DOI
10 
Bauduin T., Gypens N., Borges A. V., 2025, Methane, carbon dioxide, and nitrous oxide emissions from two clear-water and two turbid-water urban ponds in Brussels (Belgium), Biogeosciences, Vol. 22, pp. 3785-3805DOI
11 
Baulch H. M., Dillon P. J., Maranger R., Schiff S. L., 2011, Diffusive and ebullitive transport of methane and nitrous oxide from streams: Are bubble-mediated fluxes important?, Journal of Geophysical Research: Biogeosciences, Vol. 116, pp. G04028DOI
12 
Beaulieu J. J., Arango C. P., Hamilton S. K., Tank J. L., 2008, The production and emission of nitrous oxide from headwater streams in the Midwestern United States, Global Change Biology, Vol. 14, No. 4, pp. 878-894DOI
13 
Bednařík A., Hlaváčová E., Pavelka M., Šigut L., Červená T., Dušek J., Picek T., Šantrůčková H., 2024, Comparison of different methods for greenhouse gas flux estimation in a mesotrophic fishpond, JGR Biogeosciences, Vol. 129, No. 2, pp. e2023JG007597DOI
14 
Benassi R. F., de Jesus T. A., Coelho L. H. G., Hanisch W. S., Domingues M. R., Taniwaki R. H., Peduto T. A. G., da Costa D. O., Pompêo M. L. M., Mitsch W. J., 2021, Eutrophication effects on CH4 and CO2 fluxes in a highly urbanized tropical reservoir (Southeast, Brazil), Environmental Science and Pollution Research, Vol. 28, pp. 42261-42274DOI
15 
Billen G., Garnier J., Grossel A., Thieu V., Théry S., Hénault C., 2020, Modeling indirect N2O emissions along the N cascade from cropland soils to rivers, Biogeochemistry, Vol. 148, pp. 207-221DOI
16 
Bridgham S. D., Cadillo-Quiroz H., Keller J. K., Zhuang Q., 2013, Methane emissions from wetlands: Biogeochemical, microbial, and modeling perspectives from local to global scales, Global Change Biology, Vol. 19, No. 5, pp. 1325-1346DOI
17 
Casper P., Maberly S. C., Hall G. H., Finlay B. J., 2000, Fluxes of methane and carbon dioxide from a small productive lake to the atmosphere, Biogeochemistry, Vol. 49, pp. 1-19DOI
18 
Chen B., Tan E., Zou W., Han L. L., Tian L., Kao S. J., 2024, The external/internal sources and sinks of greenhouse gases (CO2, CH4, N2O) in the Pearl River Estuary and adjacent coastal waters in summer, Water Research, Vol. 249, pp. 120913DOI
19 
Christensen S., Rousk K., 2024, Global N2O emissions from our planet: Which fluxes are affected by man, and can we reduce these?, iScience, Vol. 27, No. 2, pp. 109042DOI
20 
Chung S. W., Yoo J. S., Park H. S., Schladow S. G., 2016, Estimation of CO2 emission from a eutrophic reservoir in temperate region, Journal of Korean Society on Water Environment, Vol. 32, No. 5, pp. 433-441DOI
21 
Crawford J. T., Stanley E. H., Spawn S. A., Finlay J. C., Loken L. C., Striegl R. G., 2014, Ebullitive methane emissions from oxygenated wetland streams, Global Change Biology, Vol. 20, No. 11, pp. 3408-3422DOI
22 
Deemer B. R., Harrison J. A., Li S., Beaulieu J. J., DelSontro T., Barros N., Bezerra-Neto J. F., Powers S. M., dos Santos M. A., Vonk J. A., 2016, Greenhouse gas emissions from reservoir water surfaces: A new global synthesis, BioScience, Vol. 66, No. 11, pp. 949-964DOI
23 
DelSontro T., Boutet L., St-Pierre A., 2016, Methane ebullition and diffusion from northern ponds and lakes regulated by the interaction between temperature and system productivity, Limnology and Oceanography, Vol. 61, No. S1, pp. S62-S77DOI
24 
DelSontro T., Kunz M. J., Kempter T., Wüest A., Wehrli B., Senn D. B., 2011, Spatial heterogeneity of methane ebullition in a large tropical reservoir, Environmental Science & Technology, Vol. 45, No. 23, pp. 9866-9873DOI
25 
DelSontro T., McGinnis D. F., Wehrli B., Ostrovsky I., 2015, Size does matter: Importance of large bubbles and small-scale hot spots for methane transport, Environmental Science & Technology, Vol. 49, No. 2, pp. 1268-1276DOI
26 
Deng O., Ran J., Gao X., Lin X., Lan T., Luo L., Xiong Y., Liu J., Ou D., Fei J., Huang R., 2023, CH4 and CO2 emissions in water networks of rice cultivation regions, Environmental Research, Vol. 218, pp. 115041DOI
27 
Duchemin E., Lucotte M., Canuel R., 1999, Comparison of static chamber and thin boundary layer equation methods for measuring greenhouse gas emissions from large water bodies, Environmental Science & Technology, Vol. 33, No. 2, pp. 350-357DOI
28 
Eugster W., DelSontro T., Sobek S., 2011, Eddy covariance flux measurements confirm extreme CH4 emissions from a Swiss hydropower reservoir and resolve their short-term variability, Biogeosciences, Vol. 8, pp. 2815-2831DOI
29 
2023, The Earth's Energy Budget, Climate Feedbacks and Climate Sensitivity, Climate Change 2021 – The Physical Science Basis: Working Group I Contribution to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change, pp. 923-1054DOI
30 
Gao X., Ouyang W., Lin C., Wang K., Hao F., Hao X., Lian Z., 2020, Considering atmospheric N2O dynamic in SWAT model avoids the overestimation of N2O emissions in river networks, Water Research, Vol. 174, pp. 115624DOI
31 
Gao Y., Li J., Wang S., Jia J., Wu. F., 2024, Global inland water greenhouse gas (GHG) geographical patterns and escape mechanisms under different water level, Water Research, Vol. 269, pp. 122808DOI
32 
Garnett M. H., Billett M. F., Gulliver P., Dean J. F., 2016, A new field approach for the collection of samples for aquatic 14CO2 analysis using headspace equilibration and molecular sieve traps: The super headspace method, Ecohydrology, Vol. 9, No. 4, pp. 781-789DOI
33 
Gerardo-Nieto O., Vega-Peñaranda A., Gonzalez-Valencia R., Alfano-Ojeda Y., Thalasso F., 2019, Continuous measurement of diffusive and ebullitive fluxes of methane in aquatic ecosystems by an open dynamic chamber method, Environmental Science & Technology, Vol. 53, No. 9, pp. 5159-5167DOI
34 
Ghosh S., De Sarkar K., Chowdhury A., Holmatov B., Rajakaruna P., 2023, The greenhouse gas emissions estimates of hydropower reservoirs in Vietnam using G-res Tool: bridging climate change mitigation with sustainability frameworks, IWMI Reports 344121DOI
35 
González-Piana M., Abe D., Sidagis C., De Giacomi S., Garreta C., Cuevas J., Chalar G., 2025, CO2, CH4, and N2O emissions in two major subtropical hydroelectric reservoirs in South America are linked to anthropogenic eutrophication, Earth Systems and Environment, Vol. 9DOI
36 
Gwon H. S., Choi E. J., Lee S. I., Lee H. S., Park H. R., Lee J. M., Jin J. H., 2022, Greenhouse gases emission from rice paddy under different tillage intensity during fallow season, Korean Journal of Soil Science and Fertilizer, Vol. 55, No. 4, pp. 464-474DOI
37 
Hall K. C., 1980, Gas chromatographic measurement of nitrous oxide dissolved in soil water, Journal of Chromatographic Science, Vol. 18, No. 1, pp. 22-24DOI
38 
Hao X., Yu R., Zhang Z., Qi Z., Lu X., Liu T., Gao R., 2021, Greenhouse gas emissions from the water–air interface of a grassland river: A case study of the Xilin River, Scientific Reports, Vol. 11, pp. 2659DOI
39 
Harmon T. C., 2020, Carbon gas flux to and from inland waters: support for a global observation network, Limnology, Vol. 21, No. 3, pp. 429-442Google Search
40 
He Y., Zhou X., Jia Z., Zhou L., Chen H., Liu R., Du Z., Zhou G., Shao J., Ding J., Chen K., Hartley I. P., 2023, Apparent thermal acclimation of soil heterotrophic respiration mainly mediated by substrate availability, Global Change Biology, Vol. 29, No. 4, pp. 1178-1187DOI
41 
Harrison J. A., Prairie Y. T., Mercier-Blais S., Soued C., 2021, Year-2020 global distribution and pathways of reservoir methane and carbon dioxide emissions according to the Greenhouse Gas From Reservoirs (G-res) model, Global Biogeochemical Cycles, Vol. 35, No. 6, pp. e2020GB006888DOI
42 
Hendriks D. M. D., van den Berg S., Gies E., de Klein J. J. M., 2023, Drifting chamber measurements of greenhouse gas emissions from surface waters: A comparison of flux calculation approaches, Freshwater Biology, Vol. 68, No. 12, pp. 695-709DOI
43 
Hirota M., Senga Y., Seike Y., Nohara S., Kunii H., 2007, Fluxes of carbon dioxide, methane and nitrous oxide in two contrastive fringing zones of coastal lagoon, Lake Nakaumi, Japan, Chemosphere, Vol. 68, No. 3, pp. 597-603DOI
44 
Hmoudah M., Pop C., Baciu C., 2022, Urban aqueous system as a hotspot for water–atmosphere exchange of CH4, Scientific and Technical Bulletin of Chemistry and Food Science Engineering, Vol. 19, pp. 43-52Google Search
45 
Ho L., Jerves-Cobo R., Barthel M., Six J., Bode S., Boeckx P., Goethals P., 2022, Greenhouse gas dynamics in an urbanized river system: Influence of water quality and land use, Environmental Science and Pollution Research, Vol. 29, pp. 37277-37290DOI
46 
Hope D., Dawson J. J. C., Cresser M. S., Billett M. F., 1995, A method for measuring free CO2 in upland streamwater using headspace analysis, Journal of Hydrology, Vol. 166, No. 1-2, pp. 1-14DOI
47 
Hounshell A. G., D’Acunha B. M., Breef-Pilz A., Johnson M. S., Thomas R. Q., Carey C. C., 2023, Eddy covariance data reveal that a small freshwater reservoir emits a substantial amount of carbon dioxide and methane, Journal of Geophysical Research: Biogeosciences, Vol. 128, pp. e2022JG007091DOI
48 
Hur J., Shim K. M., Lee B. T., Kim Y., Jo S., 2020, Estimation and comparison of carbon uptake in rice paddy, dry cropland and grove in South Korea using eddy covariance flux data, Korean Journal of Environmental Agriculture, Vol. 39, No. 4, pp. 334-342DOI
49 
Hwang S. H., Kim S., Jang S. H., Park S. J., 2025, Methane emission status in the crop cultivation section of major countries national greenhouse gas inventory reports following guideline changes, Journal of Korean Society of Environmental Engineers, Vol. 47, No. 9, pp. 626-636DOI
50 
Hwang Y., Kang M., Kim J., Hirata R., Kim Y., 2020, Comprehensive assessments of carbon dynamics in an intermittently irrigated rice paddy in South Korea, Agricultural and Forest Meteorology, Vol. 285-286, pp. 107933DOI
51 
2021, Climate change 2021: The physical science basis. Contribution of working group I to the sixth assessment report of the intergovernmental panel on climate changeDOI
52 
Jahangir M. M. R., Johnston P., Khalil M. I., Grant J., Somers C., Richards K. G., 2012, Evaluation of headspace equilibration methods for quantifying greenhouse gases in groundwater, Journal of Environmental Management, Vol. 111, pp. 208-212DOI
53 
Jammet M., Dengel S., Kettner E., Parmentier F. J. W., Wik M., Crill P., Friborg T., 2017, Year-round CH4 and CO2 flux dynamics in two contrasting freshwater ecosystems of the subarctic, Biogeosciences, Vol. 14, pp. 5189-5216DOI
54 
Jang S. H., Park S. J., 2025, Characteristics of methane emissions and practical mitigation strategies in rice paddy fields, Journal of Korean Society of Environmental Engineers, Vol. 47, No. 6, pp. 387-392DOI
55 
Jang S. H., Kim T. Y., Park S. J., 2023, Bridging the gap between greenhouse gas mitigation technologies and national inventories in the cropland sector: A comparative analysis and policy implications for Korea, Korean Journal of Environmental Agriculture, Vol. 42, No. 2, pp. 118-132DOI
56 
Jang S. H., Kim T., Park S. J., 2025, Comparative inventory assessment of greenhouse gas mitigation technologies in the cropland sector and policy implications for Korea, Journal of Korean Society of Environmental Engineers, Vol. 47, No. 9, pp. 661-680DOI
57 
Jensen S. A., Webb J. R., Simpson G. L., Baulch H. M., Leavitt P. R., Finlay K., 2022, Seasonal variability of CO2, CH4, and N2O content and fluxes in small agricultural reservoirs of the northern Great Plains, Frontiers in Environmental Science, Vol. 10, pp. 895531DOI
58 
Jeong H. C., Choi E. J., Lee J. S., Kim G. Y., Lee S. I., 2018, Comparison of CH4 emission between auto chamber and manual chamber in the rice paddy, Journal of Climate Change Research, Vol. 9, No. 4, pp. 377-384DOI
59 
Jeong Y. J., Lee J. M., Lee M., Lee H. S., Lee S. I., Park H. R., 2024, Changes in N2O emissions from agricultural water samples with storage time at low temperature measured with headspace methods, Korean Journal of Soil Science and Fertilizer, Vol. 57, No. 4, pp. 418-425DOI
60 
Jia J., Dungait J. A. J., Lu Y., Cui T., Yu G., Gao Y., 2023, Inland water metabolic carbon processes and associated biological mechanisms that drive carbon source-sink instability, The Innovation Geoscience, Vol. 1, No. 3, pp. 100035DOI
61 
Jiang Y., Du Y., Sun X., Deng Y., Xu J., Tian H., Han P., Gan Y., Ma T., Wang Y., 2023, Quantification of groundwater-borne greenhouse gases (CH4, CO2, N2O) fluxes to an oxbow lake in a subtropical alluvial-lacustrine plain, Applied Geochemistry, Vol. 155, pp. 105743DOI
62 
Jones M. W., Peters G. P., Gasser T., Andrew R. M., Schwingshackl C., Gütschow J., Houghton R. A., Friedlingstein P., Pongratz J., Le Quéré C., 2023, National contributions to climate change due to historical emissions of carbon dioxide, methane, and nitrous oxide since 1850, Scientific Data, Vol. 10, No. 1, pp. 155DOI
63 
Jung M., Schwalm C., Migliavacca M., Walther S., Camps-Valls G., Koirala S., Anthoni P., Besnard S., Bodesheim P., Carvalhais N., Chevallier F., Gans F., Goll D. S., Haverd V., Köhler P., Ichii K., Jain A. K., Liu J., Lombardozzi D., Nabel J. E. M. S., Nelson J. A., O’Sullivan M., Pallandt M., Papale D., Peters W., Pongratz J., Rödenbeck C., Sitch S., Tramontana G., Walker A., Weber U., Reichstein M., 2020, Scaling carbon fluxes from eddy covariance sites to globe: Synthesis and evaluation of the FLUXCOM approach, Biogeosciences, Vol. 17, No. 5, pp. 1343-1365DOI
64 
Kang M., Cho S., 2021, Progress in water and energy flux studies in Asia: A review focused on eddy covariance measurements, Journal of Agricultural Meteorology, Vol. 77, No. 1, pp. 2-23DOI
65 
Karbin S., Rezaee N., Jamali S., 2021, Estimating greenhouse gases emissions from Karun-4 water reservoir by applying G-res model, Proceedings of the 5th Asia-Pacific Group International Symposium on Water and Dams, New Delhi, India, February 24-27, 2021Google Search
66 
Keller M., Stallard R. F., 1994, Methane emission by bubbling from Gatun Lake, Panama, Journal of Geophysical Research: Atmospheres, Vol. 99, No. D4, pp. 8307-8319DOI
67 
Kenny W. T., Bohrer G., Morin T. H., Vogel C. S., Matheny A. M., Desai A. R., 2017, A numerical case study of the implications of secondary circulations to the interpretation of eddy-covariance measurements over small lakes, Boundary-Layer Meteorology, Vol. 165, pp. 311-332DOI
68 
Kim G. W., Park S. J., Kim T. Y., 2025, A study on the marginal abatement cost and optimal management plan for low-carbon agricultural activities in agricultural land, Journal of Agriculture & Life Science, Vol. 59, No. 5, pp. 165-175DOI
69 
Kim J. S., Han H., 2025, Estimating GHG absorption and reduction cost of riparian zones in the Yeongsan and Sumjin River watershed, Journal of Korea Water Resources Association, Vol. 58, No. 5, pp. 399-410DOI
70 
Kim K., Jung S., Choi Y., Peiffer S., Knorr K. H., Kim B., 2018, Methane gas emission from an artificial reservoir under Asian monsoon climate conditions, with a focus on the ebullition pathway, Korean Journal of Ecology and Environment, Vol. 51, No. 2, pp. 160-167DOI
71 
Kim S., An S., 2022, A study on the effect of the development of anaerobic respiration processes in the sediment with the water-column stratification and hypoxia and its influence on methane at Dangdong Bay in Jinhae, Korea, Ocean and Polar Research, Vol. 44, No. 1, pp. 1-11DOI
72 
Ko J., Kim Y., Ji U., Kang H., 2019, Effects of streambed geomorphology on nitrous oxide flux are influenced by carbon availability, Journal of Korea Water Resources Association, Vol. 52, No. 11, pp. 917-929DOI
73 
Krauss K. W., Carter J. A., Bianchi T. J., Bevington A. E., Anderson E. W., McKee K. L., 2016, The role of the upper tidal estuary in wetland blue carbon storage and flux, Global Biogeochemical Cycles, Vol. 30, No. 10, pp. 1605-1620DOI
74 
Krishnan A., Devarajan Y., Nagappan B., Kumar D., Upadhye V. J., 2025, Inland waterways symphony: Understanding transformation mechanisms of carbon and nitrogen emissions, Environmental Monitoring and Assessment, Vol. 197, pp. 885DOI
75 
Kumar A., Yu Z. G., Klemeš J. J., Bokhari A., 2021, A state-of-the-art review of greenhouse gas emissions from Indian hydropower reservoirs, Journal of Cleaner Production, Vol. 320, pp. 128806DOI
76 
Kwon J. H., Han Y. S., Cho Y. C., Ahn J. S., Yim G. J., 2018, Water quality and methane emission characteristics of aerobic wetlands constructed in coal mine area, Journal of the Korean Society of Mineral and Energy Resources Engineers, Vol. 55, No. 5, pp. 371-382DOI
77 
Lauerwald R., Allen G. H., Deemer B. R., Liu S., Maavara T., Raymond P., Alcott L., Bastviken D., Hastie A., Holgerson M. A., Johnson M. S., Lehner B., Lin P., Marzadri A., Ran L., Tian H., Yang X., Yao Y., Regnier P., 2023, Inland water greenhouse gas budgets for RECCAP2: 1. State-of-the-art of global scale assessments, Global Biogeochemical Cycles, Vol. 37, No. 5, pp. e2022GB007657DOI
78 
Lee E., Chung S., Park H., Kim S., Park D., 2019, Estimation of CO2 net atmospheric flux in the middle and lower Nakdong River, and influence factors analysis, Journal of Korean Society on Water Environment, Vol. 35, No. 4, pp. 316-331DOI
79 
Lee J. M., Kim H. S., Choi S. E., Lee Y., Chu Y., Lee W. K., Son Y., 2023, Strategies for estimating greenhouse gas emissions in inland wetlands: Classification systems and emission factors, Journal of Climate Change Research, Vol. 14, No. 6, pp. 715-726DOI
80 
Lee S. H., Shin S. H., Bae D. H., 2010, Recent trends in standardization techniques for hydrologic scenarios under climate change, Water and Future : Journal of Korea Water Resources Association, Vol. 43, No. 8, pp. 12-18Google Search
81 
Lee S. R., Oh H., Choi J. H., 2024, Study on the effects of stratification and sediment organic matter characteristics on methane production in Asan Lake, Journal of Korean Society on Water Environment, Vol. 40, No. 5, pp. 215-228DOI
82 
Li Y., Tian H., Yao Y., Shi H., Bian Z., Shi Y., Wang S., Maavara T., Lauerwald R., Pan S., 2024, Increased nitrous oxide emissions from global lakes and reservoirs since the pre-industrial era, Nature Communications, Vol. 15, pp. 942DOI
83 
Lin P., Du Z., Wang L., Liu J., Xu Q., Du J., Jiang R., 2023, Hotspots of riverine greenhouse gas (CH4, CO2, N2O) emissions from Qinghai Lake Basin on the northeast Tibetan Plateau, Science of the Total Environment, Vol. 857, pp. 159373DOI
84 
Lorke A., Bodmer P., Noss C., Alshboul Z., Koschorreck M., Somlai-Haase C., Bastviken D., Flury S., McGinnis D. F., Maeck A., Müller D., Premke K., 2015, Technical note: Drifting versus anchored flux chambers for measuring greenhouse gas emissions from running waters, Biogeosciences, Vol. 12, pp. 7013-7024DOI
85 
Magen C., Lapham L. L., Pohlman J. W., Marshall K., Bosman S., Casso M., Chanton J. P., 2014, A simple headspace equilibration method for measuring dissolved methane, Limnology and Oceanography: Methods, Vol. 12, No. 9, pp. 637-650DOI
86 
Martinsen K. T., Kragh T., Sand-Jensen K., 2018, A simple and cost-efficient automated floating chamber for continuous measurements of carbon dioxide gas flux on lakes, Biogeosciences, Vol. 15, No. 18, pp. 5565-5573DOI
87 
Michaelis T., Kaplar F., Baumann T., Wunderlich A., Einsiedl F., 2024, High methane ebullition throughout one year in a regulated central European stream, Scientific Reports, Vol. 14, pp. 5359DOI
88 
Min K. S., Chung S. W., Kim S. J., Kim D. K., 2022, Assessing greenhouse gas footprint and emission pathways in Daecheong Reservoir, Journal of Korea Water Resources Association, Vol. 55, No. 10, pp. 785-799DOI
89 
Min K. S., Chung S. W., Kim S. J., Kim D. K., 2026, Greenhouse gas emissions and footprint analysis of multi-purpose dam reservoirs in temperate regions using the G-res Tool, Renewable and Sustainable Energy Reviews, Vol. 225, pp. 116143DOI
90 
Miranda L. T., Whitfield C. J., 2024, The role of multiple greenhouse gas flux pathways at four prairie pothole ponds, Wetlands, Vol. 44, pp. 123DOI
91 
Montes-Pérez J. J., Irusta P., Cañas L., Mejía F., Pinaud-Brageot N., Obrador B., Puigserver D., Millán A., von Schiller D., 2025, Chlorination cessation alters greenhouse gas dynamics in artificial urban ponds, JGR: Biogeosciences, Vol. 130, No. 8, pp. e2025JG008907DOI
92 
Montes-Pérez J. J., Obrador B., Conejo-Orosa T., Rodríguez V., Marcé R., Escot C., Reyes I., Rodríguez J., Moreno-Ostos E., 2022, Spatio-temporal variability of carbon dioxide and methane emissions from a Mediterranean reservoir, Limnetica, Vol. 41, No. 1, pp. 43-60DOI
93 
Mu J., Qi J., Yu H., Hu C., Mu Y., Qu J., 2022, Dynamic chamber as a more reliable technique for measuring methane emissions from aquatic ecosystems, Science of the Total Environment, Vol. 851, pp. 158147DOI
94 
Natchimuthu S., Sundgren I., Gålfalk M., Klemedtsson L., Crill P., Danielsson Å., Bastviken D., 2016, Spatio-temporal variability of lake CH4 fluxes and its influence on annual whole lake emission estimates, Limnology and Oceanography, Vol. 61, No. S1, pp. S13-S26DOI
95 
Niu X., Shi W., Wu W., Liu S., Yang P., Li S., Yan Z., 2023, Research advances on ebullitive CH4 emissions from inland waters, Advances in Earth Science, Vol. 38, No. 8, pp. 802-814DOI
96 
Nordbo A., Launiainen S., Mammarella I., Leppäranta M., Huotari J., Ojala A., Vesala T., 2011, Long-term energy flux measurements and energy balance over a small boreal lake using eddy covariance technique, Journal of Geophysical Research: Atmospheres, Vol. 116, pp. D02119DOI
97 
Panneer Selvam B., Natchimuthu S. I., Arunachalam L., Bastviken D., 2014, Methane and carbon dioxide emissions from inland waters in India – Implications for large scale greenhouse gas balances, Global Change Biology, Vol. 20, No. 11, pp. 3397-3407DOI
98 
Paranaíba J. R., Kosten S., 2024, Mitigating inland waters’ greenhouse gas emissions: current insights and prospects, Inland Waters, Vol. 14, No. 1-2, pp. 97-110DOI
99 
Park H. S., Chung S. W., 2020, Characterizing spatiotemporal variations and mass balance of CO2 in a stratified reservoir using CE-QUAL-W2, Journal of Korean Society on Water Environment, Vol. 36, No. 6, pp. 508-520DOI
100 
Park Y., Lee T., Park Y., Han S., Ryu J., Choi W., 2025, Measurements of ozone flux and dry deposition velocity using the eddy covariance method: Pilot observations in urban areas in Busan and Ulsan, Korea, Journal of Korean Society for Atmospheric Environment, Vol. 41, No. 4, pp. 645-666DOI
101 
Peacock M., Audet J., Bastviken D., Cook S., Evans C. D., Grinham A., Holgerson M. A., Högbom L., Pickard A. E., Zieliński P., Futter M. N., 2021, Small artificial waterbodies are widespread and persistent emitters of methane and carbon dioxide, Global Change Biology, Vol. 27, pp. 5109-5123DOI
102 
Peterse I. F., Hendriks L., Weideveld S. T. J., Smolders A. J. P., Lamers L. P. M., Lücker S., Veraart A. J., 2024, Wastewater-effluent discharge and incomplete denitrification drive riverine CO2, CH4 and N2O emissions, Science of the Total Environment, Vol. 951, pp. 175797DOI
103 
Petersen S. G. G., Kristensen E., Quintana C. O., 2023, Greenhouse gas emissions from agricultural land before and after permanent flooding with seawater or freshwater, Estuaries and Coasts, Vol. 46, pp. 1459-1474DOI
104 
Pilla R. M., Williamson C. E., Zhang J., Smyth R. L., Renwick W. H., Knoll L. B., Fisher T. J., 2022, Anthropogenically driven climate and landscape change effects on inland water carbon dynamics: What have we learned and where are we going?, Global Change Biology, Vol. 28, No. 19, pp. 5601-5629DOI
105 
Podgrajsek E., Sahlée E., Bastviken D., Holst J., Lindroth A., Tranvik L., Rutgersson A., 2014, Comparison of floating chamber and eddy covariance measurements of lake greenhouse gas fluxes, Biogeosciences, Vol. 11, No. 15, pp. 4225-4233DOI
106 
Ran L., Butman D. E., Battin T. J., Yang X., Tian M., Duvert C., Hartmann J., Geeraert N., Liu S., 2021, Substantial decrease in CO2 emissions from Chinese inland waters due to global change, Nature Communications, Vol. 12, pp. 1730DOI
107 
Ray N. E., Holgerson M. A., Grodsky S. M., 2024, Immediate effect of floating solar energy deployment on greenhouse gas dynamics in ponds, Environmental Science & Technology, Vol. 58, No. 50, pp. 22104-22113DOI
108 
Reay D. S., Davidson E. A., Smith K. A., Smith P., Melillo J. M., Dentener F., Crutzen P. J., 2012, Global agriculture and nitrous oxide emissions, Nature Climate Change, Vol. 2, No. 6, pp. 410-416DOI
109 
Robbins G. A., Wang S., Stuart J. D., 1993, Using the static headspace method to determine Henry's law constants, Analytical Chemistry, Vol. 65, No. 21, pp. 3113-3118DOI
110 
Sarkar K. D., Ghosh S., Bhattacharyya S., Chowdhury A., Holmatov B., 2025, Assessing GHG emissions of a tropical large hydropower reservoir using G-res and GEE, Journal of the Indian Society of Remote Sensing, Vol. 53, pp. 1053-1064DOI
111 
Saunois M., Stavert A. R., Poulter B., Bousquet P., Canadell J. G., Jackson R. B., Raymond P. A., Dlugokencky E. J., Houweling S., Patra P. K., et al. , 2020, The global methane budget 2000-2017, Earth System Science Data, Vol. 12, No. 3, pp. 1561-1623DOI
112 
Schade J. D., Bailio J., McDowell W. H., 2016, Greenhouse gas flux from headwater streams in New Hampshire, USA: Patterns and drivers, Limnology and Oceanography, Vol. 61, No. S1, pp. S165-S174DOI
113 
Schrier-Uijl A. P., Kroon P. S., Hensen A., Leffelaar P. A., Berendse F., Veenendaal E. M., 2010, Comparison of chamber and eddy covariance-based CO2 and CH4 emission estimates in a heterogeneous grass ecosystem on peat, Agricultural and Forest Meteorology, Vol. 150, No. 6, pp. 825-831DOI
114 
Schubert C. J., Diem T., Eugster W., 2012, Methane emissions from a small wind-shielded lake determined by eddy covariance, flux chambers, anchored funnels, and boundary model calculations: A comparison, Environmental Science & Technology, Vol. 46, No. 8, pp. 4515-4522DOI
115 
Sepulveda-Jauregui A., Hoyos-Santillán J., Martinez-Cruz K., Walter Anthony K. M., Casper P., Belmonte-Izquierdo Y., Thalasso F., 2018, Eutrophication exacerbates the impact of climate warming on lake methane emission, Science of the Total Environment, Vol. 636, pp. 411-419DOI
116 
Shahan J., Chu H., Windham-Myers L., Matsumura M., Carlin J., Eichelmann E., Stuart-Haentjens E., Bergamaschi B., Nakatsuka K., Sturtevant C., Oikawa P., 2022, Combining eddy covariance and chamber methods to better constrain CO2 and CH4 fluxes across a heterogeneous restored tidal wetland, JGR: Biogeosciences, Vol. 127, No. 9, pp. e2022JG007112DOI
117 
Shi D., Li W., Hopkinson B. M., Hong H., Li D., Kao S. J., Lin W., 2015, Interactive effects of light, nitrogen source, and carbon dioxide on energy metabolism in the diatom Thalassiosira pseudonana, Limnology and Oceanography, Vol. 60, No. 5, pp. 1805-1822DOI
118 
Soued C., Bogard M. J., Finlay K., Bortolotti L. E., Leavitt P. R., Badiou P., Knox S. H., Jensen S., Mueller P., Lee S. C., Ng D., Wissel B., Chan C. N., Page B., Kowal P., 2024, Salinity causes widespread restriction of methane emissions from small inland waters, Nature Communications, Vol. 15, pp. 717DOI
119 
van Hoek W. J., Wang J., Vilmin L., Beusen A. H. W., Mogollón J. M., Müller G., Pika P. A., Liu X., Langeveld J. J., Bouwman A. F., Middelburg J. J., 2021, Exploring spatially explicit changes in carbon budgets of global river basins during the 20th century, Environmental Science & Technology, Vol. 55, No. 24, pp. 16757-16769DOI
120 
Vesala T., Eugster W., Ojala A., 2012, Eddy covariance measurements over lakes, Eddy Covariance: A Practical Guide to Measurement and Data Analysis, pp. 365-386DOI
121 
Vilmin L., Mogollón J. M., Beusen A. H. W., van Hoek W. J., Liu X., Middelburg J. J., Bouwman A. F., 2020, Modeling process‐based biogeochemical dynamics in surface fresh waters of large watersheds with the IMAGE‐DGNM framework, Journal of Advances in Modeling Earth Systems, Vol. 12, No. 11, pp. e2019MS001796DOI
122 
Wang G., Xia X., Liu S., Zhang L., Zhang S., Wang J., Xi N., Zhang Q., 2021, Intense methane ebullition from urban inland waters and its significant contribution to greenhouse gas emissions, Water Research, Vol. 189, pp. 116654DOI
123 
Wang G., Xia X., Liu S., Zhang S., Yan W., McDowell W. H., 2021, Distinctive patterns and controls of nitrous oxide concentrations and fluxes from urban inland waters, Environmental Science & Technology, Vol. 55, No. 12, pp. 8422-8431DOI
124 
Wang H., Dai Z., Krauss K. W., Trettin C. C., Noe G. B., Burton A. J., Ward E. J., 2023, Modeling impacts of saltwater intrusion on methane and nitrous oxide emissions in tidal forested wetlands, Ecological Applications, Vol. 33, No. 5, pp. e2858DOI
125 
Wang J., Vilmin L., Mogollón J. M., Beusen A. H. W., van Hoek W. J., Liu X., Pika P. A., Middelburg J. J., Bouwman A. F., 2023, Inland waters increasingly produce and emit nitrous oxide, Environmental Science & Technology, Vol. 57, No. 36, pp. 13506-13519DOI
126 
Wang Z., Chan F. K. S., Feng M., Johnson M. F., 2024, Greenhouse gas emissions from hydropower reservoirs: emission processes and management approaches, Environmental Research Letters, Vol. 19, pp. 073002DOI
127 
Webb J. R., Clough T. J., Quayle W. C., 2021, A review of indirect N2O emission factors from artificial agricultural waters, Environmental Research Letters, Vol. 16, pp. 043005DOI
128 
Webb J. R., Hayes N. M., Simpson G. L., Leavitt P. R., Baulch H. M., Finlay K., 2019, Widespread nitrous oxide undersaturation in farm waterbodies creates an unexpected greenhouse gas sink, Proceedings of the National Academy of Sciences of the United States of America, Vol. 116, No. 20, pp. 9814-9819DOI
129 
Webb J. R., Leavitt P. R., Simpson G. L., Baulch H. M., Haig H. A., Hodder K. R., Finlay K., 2019, Regulation of carbon dioxide and methane in small agricultural reservoirs: Optimizing potential for greenhouse gas uptake, Biogeosciences, Vol. 16, pp. 4211-4227DOI
130 
Wells N. S., Reshid M. Y., Hennig K., Hipsey M., Huang P., Eyre B. D., 2025, Drainage ditches (“hot spots”) and storms (“hot moments”) define aquatic greenhouse gas (CO2, CH4, N2O) emissions from the land-to-ocean aquatic continuum, Geophysical Research Letters, Vol. 52, pp. e2024GL113326DOI
131 
Wilcock R. J., Sorrell B. K., 2008, Emissions of greenhouse gases CH4 and N2O from low-gradient streams in agriculturally developed catchments, Water, Air, and Soil Pollution, Vol. 188, pp. 155-170DOI
132 
Wu S., Wang X., Liu T., He Y., Que Z., Wang J., Li H., Yu L., Zhang Y., Yuan X., 2021, Spatiotemporal variability of the nitrous oxide concentrations and fluxes from a cascaded dammed river, Frontiers in Environmental Science, Vol. 9, pp. 728489DOI
133 
Wu Y., Li D., Zhu J., Zhang G., Wang C., Zhang Y., Xu D., Tan W., Wang C., 2025, Unraveling the GHG emission patterns of inland waters in China: impact of water body types, aquatic plant life forms, and water temperature, Journal of Environmental Management, Vol. 393, pp. 127130DOI
134 
Yang Q., Chen S., Li Y., Liu B., Ran L., 2024, Carbon emissions from Chinese inland waters: Current progress and future challenges, JGR: Biogeosciences, Vol. 129, No. 2, pp. e2023JG007675DOI
135 
Yang Z., Tang C., Li X., Zhang H., Cai Y., 2019, Dynamics of dissolved greenhouse gas response to seasonal water mixing in subtropical reservoirs, Environmental Monitoring and Assessment, Vol. 191, No. 639, pp. 1-13DOI
136 
Yao Y., Tian H., Xu X., Li Y., Pan S., 2022, Dynamics and controls of inland water CH4 emissions across the conterminous United States: 1860-2019, Water Research, Vol. 224, pp. 119043DOI
137 
Yin J., Chen X., Xie W., Wen L., 2025, Urban lakes as significant sources of greenhouse gas (CO2, CH4, and N2O) emissions: Insights from field measurements and statistical analyses, Environmental Monitoring and Assessment, Vol. 197, pp. 561DOI
138 
Yu Z., Staudhammer C. L., Malone S. L., Oberbauer S. F., Zhao J., Cherry J. A., Starr G., 2023, Biophysical factors influence methane fluxes in subtropical freshwater wetlands using eddy covariance methods, Ecosystems, Vol. 26, pp. 706-723DOI
139 
Zhang Y., Qin Z., Li T., Zhu X., 2022, Carbon dioxide uptake overrides methane emission at the air-water interface of algae-shellfish mariculture ponds: Evidence from eddy covariance observations, Science of the Total Environment, Vol. 815, No. 1, pp. 152867DOI
140 
Zhang Q., Smith K., Zhao X., Jin X., Wang S., Shen J., Ren Z. J., 2021, Greenhouse gas emissions associated with urban water infrastructure: What we have learnt from China’s practice, WIREs Water, Vol. 8, No. 4, pp. e1529DOI
141 
Zhang L., Stanley E. H., Rocher-Ros G., Dean J. F., Li D., Wang Q., Zhang L., Shi W., Xie T., Xia X., 2024, System-wide greenhouse gas emissions from mountain reservoirs draining permafrost catchments on the Qinghai- Tibet Plateau, Global Biogeochemical Cycles, Vol. 38, No. 12, pp. e2024GB008112DOI
142 
Zhang W., Li H., Xiao Q., Li X., 2021, Urban rivers are hotspots of riverine greenhouse gas (N2O, CH4, CO2) emissions in the mixed-landscape Chaohu Lake basin, Water Research, Vol. 189, pp. 116624DOI
143 
Zhang Y., Wang X., Gong X., Wu S., Yuan X., Liu T., Hou C., 2021, Greenhouse gases concentrations and emissions in different inland water bodies in Chengdu Plain, Desalination and Water Treatment, Vol. 239, pp. 101-117DOI
144 
Zheng Y., Wu S., Xiao S., Yu K., Fang X., Xia L., Wang J., Liu S., Freeman C., Zou J., 2022, Global methane and nitrous oxide emissions from inland waters and estuaries, Global Change Biology, Vol. 28, No. 15, pp. 4713-4725DOI
145 
Zhou Y., Maavara T., Raymond P. A., 2024, Drivers of global riverine carbon dioxide emissions under climate and land-use change, Science China Earth Sciences, Vol. 67, pp. 1445-1458DOI
146 
Zhu L., Yu J., Van Dam B., Cao H., Pu Y., Shi W., Qin B., 2020, Optimized methods for diffusive greenhouse gas flux analyses in inland waters, Environmental Science and Pollution Research, Vol. 27, pp. 25870-25876DOI
147 
Zhu Y., Chen X., Yang Y., Xie S., 2022, Impacts of cyanobacterial biomass and nitrate nitrogen on methanogens in eutrophic lakes, Science of the Total Environment, Vol. 848, pp. 157570DOI
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