Study on CO2 and CH4 emission fluxes from Lancang River cascade reservoirs

doi:10.12006/j.issn.1673-1719.2023.188

Abstract

Abstract:

The greenhouse effect has become an important global climate issue, and inland waters are an important source of emissions of the greenhouse gases (GHG) CO₂ and CH₄. It has been found that hydropower energy, once considered clean, may cause an increase in CO₂ and CH₄ emissions from river waters as a result of damming and impounding water. In order to actively respond to the national “Dual-Carbon” goal and clarify the impact of damming and impounding on GHG emissions from water bodies, the G-res Tool, a model for evaluating the net flux of GHG emissions from reservoirs, was used to simulate the CO₂ and CH₄ emission fluxes before and after impoundment of 10 completed terrace reservoirs on the main stream of the Lancang River. The average annual GHG (CO₂ and CH₄) emission flux of the 10 reservoirs after impoundment is 162.81 g CO₂e/(m²·a), which is much lower than the global average level of reservoirs, but all of them behave as “sources” of GHGs, with an overall upward trend from upstream to downstream. Emissions are dominated by CO₂, with an annual CO₂ emission fluxes 36 times that of CH₄, which is dominated by diffuse and off-gas emissions. After considering the GHG emissions prior to reservoir impoundment and the impacts of unrelated anthropogenic sources, the average annual net flux of GHG (CO₂ and CH₄) emissions from the reservoir is 225.70 g CO₂e/(m²·a), suggesting that damming increases the release of GHGs from the reservoir waters. However, hydropower is still a relatively clean energy compared to thermal power generation.

Key words: Lancang River, Terraced power station, Reservoir greenhouse gas, Model, Net emission flux

TAO Yu-Chen, FU Kai-Dao, ZHANG Jie, YANG Li-Sha, YUAN Xi. Study on CO₂ and CH₄ emission fluxes from Lancang River cascade reservoirs[J]. Climate Change Research, 2024, 20(1): 107-117.

Figures/Tables 9

Fig. 1 Distribution of reservoirs in the Lancang River basin (Yunnan section)

Table 1 G-res Tool entry information and its sources

Fig. 2 The model framework of net greenhouse gas (GHG) emission fluxes from reservoirs [15]

Fig. 3 Assessment results of annual post-impoundment GHG emission fluxes in Lancang River in 2001-2021

Fig. 4 Assessment results of annual post-impoundment methane emission fluxes for three pathways in Lancang River in 2001-2021

Fig. 5 Assessment results of annual GHG emission fluxes of reservoirs from pre-reservoir impoundment (a) and unrelated anthropogenic (b) sources in Lancang River in 2001-2021

Fig. 6 Assessment results of annual net GHG emission fluxes of reservoirs in Lancang River in 2001-2021

Table 2 Carbon emissions and GHG emission factors over the life cycle of reservoirs in the Lancang River basin

Table 3 Emission fluxes of CO2 and CH4 from reservoirs worldwide

References 44

[1]	Fearnside P M. Hydroelectric dams in the Brazilian Amazon as sources of ‘greenhouse’ gases[J]. Environmental Conservation, 1995, 22 (1): 7-19 doi: 10.1017/S0376892900034020 URL
[2]	John W M R, Reed H, Kelly C A, et al. Are hydroelectric reservoirs significant sources of greenhouse gases?[J]. Ambio, 1993, 22 (4): 246-248
[3]	Dos Santos M A, Rosa L P, Sikar B, et al. Gross greenhouse gas fluxes from hydro-power reservoir compared to thermo-power plants[J]. Energy Policy, 2006, 34 (4): 481-488 doi: 10.1016/j.enpol.2004.06.015 URL
[4]	Barros N, Cole J J, Tranvik L J, et al. Carbon emission from hydroelectric reservoirs linked to reservoir age and latitude[J]. Nature Geoscience, 2011, 4 (9): 593-596 doi: 10.1038/ngeo1211
[5]	Teodoru C R, Bastien J, Bonneville M C, et al. The net carbon footprint of a newly created boreal hydroelectric reservoir[J]. Global Biogeochemical Cycles, 2012, 26: GB2016
[6]	孙志禹, 陈永柏, 李翀, 等. 中国水库温室气体研究(2009—2019): 回顾与展望[J]. 水利学报, 2020, 51 (3): 253-267.
	Sun Z Y, Chen Y B, Li C, et al. Research of reservoir greenhouse gas emission in China (2009-2019): review and outlook[J]. Journal of Hydraulic Engineering, 2020, 51 (3): 253-267 (in Chinese)
[7]	IPCC. IPCC special report on renewable energy sources and climate change mitigation[M]. Cambridge: Cambridge University Press, 2012
[8]	Lima I C. Biogeochemical distinction of methane releases from two Amazon hydroreservoirs[J]. Chemosphere, 2005, 59 (11): 1697-1702 pmid: 15894055
[9]	Zhao J, Zhang M, Xiao W, et al. An evaluation of the flux-gradient and the eddy covariance method to measure CH₄, CO₂, and H₂O fluxes from small ponds[J]. Agricultural and Forest Meteorology, 2019, 275: 255-264 doi: 10.1016/j.agrformet.2019.05.032 URL
[10]	Bastviken D, Cole J, Pace M, et al. Methane emissions from lakes: dependence of lake characteristics, two regional assessments, and a global estimate[J]. Global Biogeochemical Cycles, 2004, 18 (4): GB4009
[11]	Hansen C, Pilla R, Matson P, et al. Variability in modelled reservoir greenhouse gas emissions: comparison of select US hydropower reservoirs against global estimates[J]. Environmental Research Communications, 2022, 4 (12): 121008 doi: 10.1088/2515-7620/acae24
[12]	Levasseur A, Mercier-Blais S, Prairie Y T, et al. Improving the accuracy of electricity carbon footprint: estimation of hydroelectric reservoir greenhouse gas emissions[J]. Renewable and Sustainable Energy Reviews, 2021, 136: 110433 doi: 10.1016/j.rser.2020.110433 URL
[13]	张斌, 李哲, 李翀, 等. 水库温室气体净通量评估模型(G-res Tool)及在长江上游典型水库初步应用[J]. 湖泊科学, 2019, 31 (5): 1479-1488.
	Zhang B, Li Z, Li C, et al. The net GHG flux assessment model of reservoir (G-res Tool) and its application in reservoirs in upper reaches of Yangtze River in China[J]. Journal of Lake Sciences, 2019, 31 (5): 1479-1488 (in Chinese) doi: 10.18307/2019.0510 URL
[14]	李雨晨, 秦宇, 杨柳, 等. 长江上游大中型水库碳排放量估算与分析: 以IPCC国家温室气体清单指南为基础[J]. 湖泊科学, 2023, 35 (1): 131-145.
	Li Y C, Qin Y, Yang L, et al. Estimation and analysis of carbon emission from the large-and medium-sized reservoirs in the upper reaches of Changjiang River: on the basis of the IPCC national greenhouse gas inventory[J]. Journal of Lake Sciences, 2023, 35 (1): 131-145 (in Chinese)
[15]	Prairie Y T, Alm J, Harby A, et al. The GHG reservoir tool (G-res) technical documentation[M]. Joint publication of the UNESCO Chair in Global Environmental Change and the International Hydropower Association, 2022
[16]	United Nations Educational, Scientific and Cultural Organization (UNESCO), International Hydropower Association (IHA). The UNESCOLHA measurement specification guidance for evaluating the GHG status of man-made freshwater reservoirs[R]. London: International Hydropower Association, 2009
[17]	Yvon-Durocher G, Allen A P, Bastviken D, et al. Methane fluxes show consistent temperature dependence across microbial to ecosystem scales[J]. Nature, 2014, 507 (7493): 488-491 doi: 10.1038/nature13164
[18]	刘丛强, 汪福顺, 王雨春, 等. 河流筑坝拦截的水环境响应: 来自地球化学的视角[J]. 长江流域资源与环境, 2009, 18 (4): 384-396.
	Liu C Q, Wang F S, Wang Y C, et al. Responses of aquatic environment to river damming: from the geochemical view[J]. Resources and Environment in the Yangtze Basin, 2009, 18 (4): 384-396 (in Chinese)
[19]	张翎, 王远见, 夏星辉. 水库建成与运行对温室气体排放的影响[J]. 环境科学学报, 2022, 42 (1): 298-307.
	Zhang L, Wang Y J, Xia X H. Influence of reservoir construction and operation on greenhouse gas emission[J]. Acta Scientiae Circumstantiae, 2022, 42 (1): 298-307 (in Chinese)
[20]	Xiao Q T, Xu X F, Duan H T, et al. Eutrophic Lake Taihu as a significant CO₂source during 2000-2015[J]. Water Research, 2020, 170: 115331. doi: 10.1016/j.watres.2019.115331 URL
[21]	赵小杰, 赵同谦, 郑华, 等. 水库温室气体排放及其影响因素[J]. 环境科学, 2008 (8): 2377-2384.
	Zhao X J, Zhao T Q, Zheng H, et al. Greenhouse gas emission from reservoir and its influence factors[J]. Environmental Science, 2008 (8): 2377-2384 (in Chinese)
[22]	Harrison J A, Prairie Y T, Mercier-Blais S, et al. Year-2020 global distribution and pathways of reservoir methane and carbon dioxide emissions according to the greenhouse gas from reservoirs (G-res) model[J]. Global Biogeochemical Cycles, 2021, 35 (6): e2020GB006888
[23]	Abril G, Guérin F, Richard S, et al. Carbon dioxide and methane emissions and the carbon budget of a 10-year old tropical reservoir (Petit Saut, French Guiana)[J]. Global Biogeochemical Cycles, 2005, 19 (4): GB4007
[24]	Soued C, Prairie Y T. The carbon footprint of a Malaysian tropical reservoir: measured versus modeled estimates highlight the underestimated key role of downstream processes[J]. Biogeosciences, 2019, 17 (2): 515-527 doi: 10.5194/bg-17-515-2020 URL
[25]	Shi W, Maavara T, Chen Q, et al. Spatial patterns of diffusive greenhouse gas emissions from cascade hydropower reservoirs[J]. Journal of Hydrology, 2023, 619: 129343 doi: 10.1016/j.jhydrol.2023.129343 URL
[26]	杜琪琪, 李伯根, 蔡虹明, 等. 澜沧江梯级水库水化学特征及其对水-气界面CO₂通量的影响[J]. 地球与环境, 2023, 51 (1): 36-46.
	Du Q Q, Li B G, Cai H M, et al. Hydrochemical characteristics of cascade reservoirs water along the Lancangjiang River and the relative influence on CO₂ flux at water/air interface[J]. Earth and Environment, 2023, 51 (1): 36-46 (in Chinese)
[27]	Wagner D, Pfeiffer E M. Two temperature optima of methane production in a typical soil of the Elbe River marshland[J]. FEMS Microbiology Ecology, 1997, 22 (2): 145-153 doi: 10.1111/j.1574-6941.1997.tb00366.x URL
[28]	Raymond P A, Zappa C J, Butman D, et al. Scaling the gas transfer velocity and hydraulic geometry in streams and small rivers[J]. Limnology and Oceanography: Fluids and Environments, 2012, 2 (1): 41-53 doi: 10.1215/lof3.v2.1 URL
[29]	Borges A V, Delilie B, Schiettecatte L S, et al. Gas transfer velocities of CO₂ in three European estuaries (Randers Fjord, Scheldt, and Thames)[J]. Limnology and Oceanography, 2004, 49 (5): 1630-1641 doi: 10.4319/lo.2004.49.5.1630 URL
[30]	夏欣, 钟权. 水电站生命周期温室气体排放研究综述[J]. 中国农业水利水电, 2020 (11): 188-192, 198.
	Xia X, Zhong Q. Research overview of life cycle greenhouse gas emissions from hydropower plants[J]. China Rural Water and Hydropower, 2020 (11): 188-192, 198 (in Chinese)
[31]	Maavara T, Chen Q, van Meter K, et al. River dam impacts on biogeochemical cycling[J]. Nature Reviews Earth & Environment, 2020, 1 (2): 103-116
[32]	Deemer B R, Harrison J A, Li S, et al. Greenhouse gas emissions from reservoir water surfaces: a new global synthesis[J]. Bioscience, 2016, 66 (11): 949-964 doi: 10.1093/biosci/biw117 pmid: 32801383
[33]	Li S Y, Bush R T, Santos I R, et al. Large greenhouse gases emissions from China’s lakes and reservoirs[J]. Water Research, 2018, 147: 13-24 doi: 10.1016/j.watres.2018.09.053 URL
[34]	Li S, Wang F, Luo W, et al. Carbon dioxide emissions from the Three Gorges Reservoir, China[J]. Acta Geochimica, 2017, 36 (4): 645-657 doi: 10.1007/s11631-017-0154-6 URL
[35]	赵登忠, 谭德宝, 汪朝辉, 等. 水布垭水库水气界面二氧化碳交换规律研究[J]. 人民长江, 2012, 43 (8): 65-70.
	Zhao D Z, Tan D B, Wang Z H, et al. Research on exchange law of CO₂ at water-air interface of Shuibuya Reservoir[J]. Yangtze River, 2012, 43 (8): 65-70 (in Chinese)
[36]	陈敏, 许浩霆, 郑祥旺, 等. 夏季降雨事件对水库温室气体通量变化的影响: 来自湖北官庄水库的高频观测[J]. 湖泊科学, 2021, 33 (6): 1857-1870.
	Chen M, Xu H T, Zheng X W, et al. Impacts of summer rainfall events on the dynamics of greenhouse gas fluxes revealed by high-frequency observation from Guanzhuang Reservoir, Hubei province[J]. Journal of Lake Sciences, 2021, 33 (6): 1857-1870 (in Chinese) doi: 10.18307/2021.0619 URL
[37]	Wang X F, He Y X, Yuan X Z, et al. Greenhouse gases concentrations and fluxes from subtropical small reservoirs in relation with watershed urbanization[J]. Atmospheric Environment, 2017, 154: 225-235 doi: 10.1016/j.atmosenv.2017.01.047 URL
[38]	Duchemin E, Lucotte M, Canuel R, et al. Comparison of greenhouse gas emissions from an old tropical reservoir with those from other reservoirs worldwide[J]. International Association of Theoretical and Applied Limnology, Proceedings, 2001, 27: 1391-1395
[39]	Dos Santos M A, Rosa L P, Sikar B, et al. Gross greenhouse gas fluxes from hydropower reservoir com-pared to thermo-power plants[J]. Energy Policy, 2006, 34: 481-488 doi: 10.1016/j.enpol.2004.06.015 URL
[40]	St Louis V L, Kelly C A, Duchemin E, et al. Reservoir surfaces as sources of greenhouse gases to the atmosphere: a global estimate[J]. Bioscience, 2000, 50 (9): 766-775 doi: 10.1641/0006-3568(2000)050[0766:RSASOG]2.0.CO;2 URL
[41]	Gunkel G. Hydropower: a green energy? Tropical reservoirs and greenhouse gas emissions[J]. Clean: Soil, Air, Water, 2009, 37 (9): 726-734 doi: 10.1002/clen.v37:9 URL
[42]	Knoll L B, Vanni M J, Renwick W H, et al. Temperate reservoirs are large carbon sinks and small CO₂ sources: results from high-resolution carbon budgets[J]. Global Biogeochemical Cycles, 2013, 27 (1): 52-64 doi: 10.1002/gbc.v27.1 URL
[43]	刘胜强, 毛显强, 邢有凯. 中国新能源发电生命周期温室气体减排潜力比较和分析[J]. 气候变化研究进展, 2012, 8 (1): 48-53.
	Liu S Q, Mao X Q, Xing Y K. Estimation and comparison of greenhouse gas mitigation potential of new energy by life circle assessment in China[J]. Climate Change Research, 2012, 8 (1): 48-53 (in Chinese)
[44]	杜海龙, 李哲, 郭劲松. 基于ISO14067的长江上游某水电项目碳足迹分析[J]. 长江流域资源与环境, 2017, 26 (7): 1102-1110.
	Du H L, Li Z, Guo J S. Carbon footprint of a large hydropower project in the upstream of the Yangtze: following ISO14067[J]. Resources and Environment in the Yangtze Basin, 2017, 26 (7): 1102-1110 (in Chinese)

Study on CO₂ and CH₄ emission fluxes from Lancang River cascade reservoirs

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