窟野河水-气界面CO2交换通量变化特征及其影响因素分析
收稿日期: 2020-06-29
修回日期: 2020-08-26
网络出版日期: 2021-04-25
基金资助
国家自然科学基金(41807318);香港研究资助局(27300118)
Variations of CO2 exchange in the Kuye River basin and its influencing factors
Received date: 2020-06-29
Revised date: 2020-08-26
Online published: 2021-04-25
近年来内陆水体CO2释放受到广泛关注,为揭示黄土高原地区内陆水体CO2的释放特征,于2018年7月和10月及2019年3月和6月利用LI-7000 CO2分析仪对窟野河及代表性水库开展了高频次的水体CO2分压(pCO2)和水-气界面CO2交换通量(FCO2)观测,并分析其时空变化规律。结果表明:窟野河水体pCO2和FCO2(分别为996 μatm和94.5 mmol·m-2·d-1)均高于水库(分别为752 μatm和10.3 mmol·m-2·d-1)。FCO2季节性差异明显:对于河流而言,表现为秋季最高(165.7 mmol·m-2·d-1),春季最低(42.9 mmol·m-2·d-1);对于水库而言,变化趋势则完全相反,表现为春季最高(16.6 mmol·m-2·d-1),秋季最低(-5.4 mmol·m-2·d-1)。生物地球化学活性更强的支流FCO2(107.4 mmol·m-2·d-1)高出干流(66.5 mmol·m-2·d-1)约50%;同时,位于中下游黄土丘陵区的水库FCO2(16.4 mmol·m-2·d-1)显著高于位于上游呼鄂丘陵区的水库FCO2(1.2 mmol·m-2·d-1)。整体来看,流域水体pCO2受碳酸盐体系影响最大,有机碳分解作用次之;流速是控制水-气界面气体交换速率的关键因素。在年尺度上,窟野河的河流与水库水体均为大气持续碳源。窟野河平均CO2释放量与我国长江及国外温带河流相近,但低于黄河中游的其他支流。
关键词: 二氧化碳交换(FCO2); 二氧化碳分压(pCO2); 时空变化; 水库; 窟野河
史红岩,冉立山,岳荣,于瑞宏,赵艳霞,吕喜玺 . 窟野河水-气界面CO2交换通量变化特征及其影响因素分析[J]. 干旱区研究, 2021 , 38(2) : 369 -379 . DOI: 10.13866/j.azr.2021.02.08
This study aimed to examine the riverine CO2 emissions on the Loess Plateau. The river water CO2 partial pressure (pCO2) and CO2 outgassing across the water-air interface (FCO2) in the Kuye River basin, situated in the northern Loess Plateau, was holistically investigated in July and October 2018 and March and June 2019 using a LI-7000 CO2 analyzer. Both pCO2 and FCO2 were higher in rivers (996 μatm and 94.5 mmol·m-2·d-1, respectively) than in reservoirs (752 μatm and 10.3 mmol·m-2·d-1, respectively). Meanwhile, the FCO2 exhibited pronounced seasonal variations. For the river waters, the highest FCO2 of 165.7 mmol·m-2·d-1 occurred in autumn, and the lowest FCO2 of 42.9 mmol·m-2·d-1 occurred in spring. For the reservoir waters, the opposite was observed with the highest FCO2 of 16.6 mmol·m-2·d-1 occurring in spring and the lowest FCO2 of -5.4 mmol·m-2·d-1 occurring in autumn. Spatially, the FCO2 in the tributary rivers (107.4 mmol·m-2·d-1) with a stronger biogeochemical activity was significantly higher than that in the Kuye mainstream (66.5 mmol·m-2·d-1) by 50%. While for reservoirs, the FCO2 of the reservoir waters (1.2 mmol·m-2·d-1) in the upper sandy hilly area was lower than that in the middle and lower loess hilly area (16.4 mmol·m-2·d-1). In summary, the pCO2 was mostly affected by the carbonate system, followed by dissolved organic carbon. Additionally, flow velocity had a substantial impact on the gas transfer velocity (k), whereas there was no significant correlation between k and wind speed. On an annual scale, both rivers and reservoirs were strong carbon sources for the atmosphere, and their average effluxes were close to that of the Yangtze River while substantially lower than that of the other tributaries in the middle Yellow River Basin.
[1] | Striegl R G, Dornblaser M M, Mcdonald C P, et al. Carbon dioxide and methane emissions from the Yukon River system[J]. Global Biogeochemical Cycles, 2012,26(4):GB0E05. |
[2] | Cole J J, Prairie Y T, Caraco N F, et al. Plumbing the global carbon cycle: Integrating inland waters into the terrestrial carbon budget[J]. Ecosystems, 2007,10(1):171-184. |
[3] | Abril G, Martinez J M, Artigas L F, et al. Amazon River carbon dioxide outgassing fuelled by wetlands[J]. Nature, 2014,505(7483):395-398. |
[4] | Battin T J, Luyssaert S, Kaplan L A, et al. The boundless carbon cycle[J]. Nature Geoscience, 2009,2(9):598-600. |
[5] | Butman D, Stackpoole S, Stets E, et al. Aquatic carbon cycling in the conterminous United States and implications for terrestrial carbon accounting[J]. Proceedings of the National Academy of Sciences, 2016,113(1):58-63. |
[6] | Raymond P A, Hartmann J, Lauerwald R, et al. Global carbon dioxide emissions from inland waters[J]. Nature, 2013,503(7476):355-359. |
[7] | Davidson E A, Figueiredo R O, Markewitz D, et al. Dissolved CO2 in small catchment streams of eastern Amazonia: A minor pathway of terrestrial carbon loss[J]. Journal of Geophysical Research: Biogeosciences, 2010,115(G4):470-479. |
[8] | 宋鲁萍. 黄河三角州滨海盐碱地CO2、N2O通量特征及影响因素研究[D]. 烟台: 中国科学院烟台海岸带研究所, 2014. |
[8] | [ Song Luping. Research on CO2、N2O Flux Characteristics and Influencing Factors of Coastal Saline-Alkali Land in Three California Yellow River[D]. Yantai: Yantai Institute of Coastal Zone Research, Chinese Academy of Sciences, 2014. ] |
[9] | 杨欢. 黄河中游pCO2的时空变化特征研究[D]. 呼和浩特: 内蒙古大学, 2015. |
[9] | [ Yang Huan. Study on the Characteristics of Spatio-temporal Variation of pCO2 in the Middle Reaches of the Yellow River[D]. Huhhot: Inner Mongolia University, 2015. ] |
[10] | 慕星, 张晓明. 皇甫川流域水沙变化及驱动因素分析[J]. 干旱区研究, 2013,30(5):933-939. |
[10] | [ Mu Xing, Zhang Xiaoming. The variation of runoff volume and sediment load and its driving factors in Huangfuchuan River Watershed[J]. Arid Zone Research, 2013,30(5):933-939. ] |
[11] | 袁水龙, 谢天明. 窟野河暴雨洪水泥沙特征分析[J]. 陕西水利, 2018(1):40-43. |
[11] | [ Yuan Shuilong, Xie Tianming. Analysis of the characteristics of the storm flood cement sand in Kuye River[J]. Shaanxi Water Resources, 2018(1):40-43. ] |
[12] | Raymond P A, Zappa C J, Butman D, et al. Scaling the gas transfer velocity and hydraulic geometry in streams and small riversr[J]. Limnology and Oceanography: Fluids and Environments, 2012,2(1):41-53. |
[13] | Ran L, Lu X X, Yang H, et al. CO2 outgassing from the Yellow River network and its implications for riverine carbon cycle[J]. Journal of Geophysical Research: Biogeosciences, 2015,120(7):1334-1347. |
[14] | 吴飞红. 典型岩溶溪流水-气界面CO2交换系数(k)及其影响因素研究[D]. 重庆: 西南大学, 2018. |
[14] | [ Wu Feihong. The Gas Exchange Coefficient (k) of CO2 and its Influencing Factors Across Water-Air Interface in a Typical Karst Groundwater-Fed Stream[D]. Chongqing: Southwest University, 2018. ] |
[15] | Wanninkhof R. Relationship between wind speed and gas exchange over the ocean[J]. Journal of Geophysical Research, 1992,97(5):7373-7382. |
[16] | 王宝森. 考虑耗水量估算黄河流域化学风化大气CO2消耗量[D]. 青岛: 中国海洋大学, 2011. |
[16] | [ Wang Baosen. Estimating CO2 Consumption of Chemical Weathering Atmosphere in the Yellow River Basin Considering Water Consumption[D]. Qingdao: Ocean University, 2011. ] |
[17] | 李凌宇, 于瑞宏, 田明扬, 等. 黄河FCO2时空变化及其影响因素——以头道拐水文站为例[J]. 生态学报, 2017,37(22):7636-7646. |
[17] | [ Li Lingyu, Yu Ruihong, Tian Mingyang, et al. Spatial-temporal variations and influencing factors of carbon dioxide evasion from the Yellow River: An example of the Toudaoguai Gauging Station[J]. Acta Ecologica Sinica, 2017,37(22):7636-7646. ] |
[18] | Ran L, Li L, Tian M, et al. Riverine CO2, emissions in the Wuding River catchment on the Loess Plateau: Environmental controls and dam impoundment impact[J]. Journal of Geophysical Research: Biogeosciences, 2017,122(6):1439-1455. |
[19] | Reiman J, Xu Y. Diel variability of pCO2 and CO2 outgassing from the lower Mississippi River: Implications for riverine CO2 outgassing estimation[J]. Water, 2018,11(13):2-15. |
[20] | Else B G T, Galley R G, Lansard B, et al. Further observations of a decreasing atmospheric CO2 uptake capacity in the Canada Basin (Arctic Ocean) due to sea ice loss[J]. Geophysical Research Letters, 2013,40(6):1132-1137. |
[21] | 王建, 丁永建, 许民, 等. 天山科其喀尔冰川区复杂下垫面CO2通量贡献区分析[J]. 干旱区研究, 2018,35(6):1512-1520. |
[21] | [ Wang Jian, Ding Yongjian, Xu Min, et al. CO2 carbon flux over moraine area of the Koxkar Glacier in the Tianshan Mountains[J]. Arid Zone Research, 2018,35(6):1512-1520. ] |
[22] | Duvert C, Bossa M, Tyler K J, et al. Groundwater-derived DIC and carbonate buffering enhance fluvial CO2 evasion in two Australian tropical rivers[J]. Global Biogeochemical Cycles, 2019,124(2):312-327. |
[23] | Stets E G, Butman D, Mcdonald C P, et al. Carbonate buffering and metabolic controls on carbon dioxide in rivers[J]. Global Biogeochemical Cycles, 2017,31(4):663-677. |
[24] | 宫辰, 杨现坤, 田明扬, 等. 黄河源区水库二氧化碳逸出暖季变化规律及影响因素分析——以刘家峡水库为例[J]. 环境科学学报, 2018,38(7):2919-2930. |
[24] | [ Gong Chen, Yang Xiankun, Tian Mingyang, et al. Variations of CO2 evasion from reservoirs and its influencing factors in warm season in the headwater region of the Yellow River: A case study of the Liujiaxia Reservoir[J]. Acta Scientiae Circumstantiae, 2018,38(7):2919-2930. ] |
[25] | Krasakopoulou E, Rapsomanikis S, Papadopoulos A, et al. Partial pressure and air-sea CO2 flux in the Aegean Sea during February[J]. Continental Shelf Research, 2009,29(11-12):1477-1488. |
[26] | Zhang L J, Wang L, Cai W J, et al. Impact of human activities on organic carbon transport in the Yellow River[J]. Biogeosciences, 2013,10(4):2513-2524. |
[27] | Takahashi T, Olafsson J, Goddard J G, et al. Seasonal variation of CO2 and nutrients in the high-latitude surface oceans: A comparative study[J]. Global Biogeochemical Cycles, 1993,7(4):843-878. |
[28] | 岳荣, 史红岩, 冉立山, 等. 融冰期与非融冰期水库CO2逸出昼夜变化及CO2分压影响因素研究[J]. 环境科学学报, 2020,40(2):320-328. |
[28] | [ Yue Rong, Shi Hongyan, Ran Lishan, et al. Study on diurnal variation of CO2 flux from reservoir and the influencing factors of partial pressure of CO2 in melting and non-melting seasons[J]. Acta Scientiae Circumstantiae, 2020,40(2):320-328. ] |
[29] | Nebbioso A, Piccolo A. Molecular characterization of dissolved organic matter (DOM): A critical review[J]. Analytical and Bioanalytical Chemistry, 2013,405(1):109-124. |
[30] | Yao G, Gao Q, Wang Z, et al. Dynamics of CO2 partial pressure and CO2 outgassing in the lower reaches of the Xijiang River, a subtropical monsoon river in China[J]. Science of the Total Environment, 2007,376(1-3):255-266. |
[31] | Halbedel S, Koschorreck M. Regulation of CO2 emissions from temperate streams and reservoirs[J]. Biogeosciences, 2013,10(11):7539-7551. |
[32] | Tamooh F, Meysman F J R, Borges A V, et al. Sediment and carbon fluxes along a longitudinal gradient in the lower Tana River (Kenya)[J]. Journal of Geophysical Research: Biogeosciences, 2014,119(7):1340-1353. |
[33] | Chun L Y, Qiang L C, Lu W S, et al. Seasonal variability of pCO2 in the two karst reservoirs, Hongfeng and Baihua Lakes in Guizhou Province, China[J]. Environmental Science, 2007,28(12):2674-2681. |
[34] | Alin Simone R, Rasera Maria de Fátima F L, Salimon Cleber I, et al. physical controls on carbon dioxide transfer velocity and flux in low-gradient river systems and implications for regional carbon budgets[J]. Journal of Geophysical Research: Biogeosciences, 2011,116(1):241-259. |
[35] | 陈银波. 喀斯特小流域水-气界面二氧化碳释放及其影响因素研究[D]. 贵阳: 贵州大学, 2019. |
[35] | [ Chen Yinbo. Carbon Dioxide Release from Water-air Interface in Karst Watershed and its Influencing Factors: A Case Study of Aha Lake into the Lake[D]. Guiyang: Guizhou University, 2019. ] |
[36] | 王钰祺, 吕东珂. 泥河水库秋季水-气界面CO2通量日变化特征及影响因子分析[J]. 森林工程, 2011,27(2):19-22. |
[36] | [ Wang Yuqi, Lyu Dongke. Analysis on influencing factors and diurnal variation of CO2 fluxes across water-air interface of Nihe reservoir in autumn[J]. Forest Engineering, 2011,27(2):19-22. ] |
[37] | 吕东珂. 哈尔滨周边泥炭型水库水-气界面CO2通量研究[D]. 哈尔滨: 东北林业大学, 2013. |
[37] | [ Lyu Dongke. Study on CO2 Flux at the Water-air Interface of Peatland Reservoirs Around Harbin[D]. Harbin: Northeast Forestry University, 2013. ] |
[38] | Wanninkhof R, Tri?anes J. The impact of changing wind speeds on gas transfer and its effect on global air-sea CO2 fluxes[J]. Global Biogeochemical Cycles, 2017,31(6):961-974. |
[39] | Crusius J, Wanninkhof R. Gas transfer velocities measured at low wind speed over a lake[J]. Limnology and Oceanography, 2003,48(3):1010-1017. |
[40] | Zhai W, Dai M, Guo X, et al. Carbonate system and CO2 degassing fluxes in the inner estuary of Changjiang (Yangtze) River, China[J]. Marine Chemistry, 2007,107(3):342-356. |
[41] | Tian M, Yang X, Ran L, et al. Impact of land cover types on riverine CO2 outgassing in the Yellow River source region[J]. Water, 2019,11(11):18. |
[42] | Crawford J T, Dornblaser M M, Stanley E H, et al. Source limitation of carbon gas emissions in high-elevation mountain streams and lakes[J]. Journal of Geophysical Research: Biogeosciences, 2015,120(5):952-964. |
[43] | Schelker J, Singer G A, Ulseth A J, et al. CO2 evasion from a steep, high gradient stream network: Importance of seasonal and diurnal variation in aquatic pCO2 and gas transfer[J]. Limnology and Oceanography, 2016,61(5):1826-1838. |
[44] | Borges A V, Darchambeau F, Lambert T, et al. Variations of dissolved greenhouse gases (CO2, CH4, N2O) in the Congo River network overwhelmingly driven by fluvial-wetland connectivity[J]. Biogeoences Discussions, 2019,16(19):3801-3834. |
[45] | 梁顺田, 王雨春, 胡明明, 等. 夏季朱衣河二氧化碳分压分布特征及影响因素分析[J]. 中国水利水电科学研究院学报, 2017,15(2):153-160. |
[45] | [ Liang Shuntian, Wang Yuchun, Hu Mingming, et al. Distributions of partial pressure of carbon dioxide and its affecting factors in the Zhuyi River in summer[J]. Journal of China Institute of Water Resources and Hydropower Research, 2017,15(2):153-160. ] |
[46] | Aufdenkampe A K, Mayorga E, Raymond P A, et al. Riverine coupling of biogeochemical cycles between land, oceans, and atmosphere[J]. Frontiers in Ecology and the Environment, 2011,9(1):53-60. |
[47] | Elizabeth León-Palmero, Rafael Morales-Baquero, Isabel Reche. Greenhouse gas fluxes from reservoirs determined by watershed lithology, morphometry, and anthropogenic pressure[J]. Environmental Research Letters, 2020,15(4):1-12. |
[48] | Drake T W, Raymond P A, Spencer R G M. Terrestrial carbon inputs to inland waters: A current synjournal of estimates and uncertainty[J]. Limnology and Oceanography Letters, 2018,3(3):132-142. |
/
〈 | 〉 |