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Temporal and Spatial Effects of River Input on Dissolved Organic Matter Composition in Lake Bosten |
JIANG Xin-tong1, 2, 3, XIAO Qi-tao3, LI Yi-min1, 2, LIAO Yuan-shan1, 2, LIU Dong3*, DUAN Hong-tao1, 2, 3* |
1. School of City and Environment, Northwest University, Xi’an 710127, China
2. Shaanxi Key Laboratory of Surface System and Environmental Carrying Capacity, Northwest University, Xi’an 710127, China
3. Key Laboratory of Watershed Geography, Chinese Academy of Sciences, Nanjing Institute of Geography and Lakes, Chinese Academy of Sciences, Nanjing 210008, China
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Abstract Lake Bosten is the largest inland throughput freshwater lake in the northwest arid zone of China. In recent years, the lake ecosystem and the drinking water safety of the surrounding residents have been seriously affected by the increase in human activities and wastewater discharge in the basin, and the impact of riverine input on the lake water quality needs to be focused on. In this study, the three-dimensional fluorescence spectra of coloured dissolved organic matter (CDOM) measured in summer and autumn were analysed in parallel.Three fractions of CDOM from Lake Bosten were identified: terrestrial humic fraction C1, tyrosine-like fraction C2 and tryptophan-like fraction C3. The effect of river input on the DOM of Lake Bosten was also analysed based on Pearson correlation. The results show that river input’s influence on Lake Bosten’s DOM differs between seasons and is directly related to the seasonal changes in river water quality. In summer, the water entering the lake from the Kaidu River mainly comes from winter snowmelt and carries a large amount of terrestrial humus into the lake, while in autumn, it is mainly glacial meltwater. The content of terrestrial humus is reduced as the flow into the lake increases, showing that the overall DOM concentration near the estuary is higher in summer and lower in autumn. The three components C1, C2 and C3, were found to be more abundant in the western part of the lake where the Kaidu River and the Yellow Water Ditch enter the lake, and the three components were similarly affected by seasonality. The correlation between DOM and conductivity was also carried out at sampling points near the mouth of the Kaidu River and other areas. It was found that the influence of external river input on the DOM of Lake Bosten was mainly concentrated near the mouth of the river, and the relationship between DOC and CDOM in the area near the mouth of the river was significant so that the CDOM could be inferred by remote sensing before estimating the DOM content. The study of the influence of river inputs on the composition of dissolved organic matter in Lake Bosten in different seasons is of great importance to protect the lake’s ecological environment and improve the lake’s water quality.
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Received: 2022-02-20
Accepted: 2022-06-06
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Corresponding Authors:
LIU Dong, DUAN Hong-tao
E-mail: dliu@niglas.ac.cn;htduan@niglas.ac.cn
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[1] Jiang T, Wang D Y, Wei S Q, et al. Science of the Total Environment, 2018, 636: 249.
[2] Wang M, Chen Y G. Chemosphere, 2018, 201: 96.
[3] Huang M, Li Z W, Luo N L, et al. Science of the Total Environment, 2019, 646: 220.
[4] Stedmon C A, Markager S, Bro R. Marine Chemistry, 2003, 82(3): 239.
[5] CHENG Qing-lin, ZHENG Bing-hui, WANG Sheng-rui, et al(程庆霖, 郑丙辉, 王圣瑞, 等). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2014, 34(3): 698.
[6] SHAO Tian-tian, ZHAO Ying, SONG Kai-shan, et al(邵田田, 赵 莹, 宋开山, 等). Environmental Science(环境科学), 2014, 35(10): 3755.
[7] LI Si-jia, SONG Kai-shan, CHEN Zhi-wen, et al(李思佳, 宋开山, 陈智文, 等). Journal of Lake Sciences(湖泊科学), 2015, 27(5): 941.
[8] SHAO Tian-tian, LI Liu-yang, WANG Tao, et al(邵田田, 李柳阳, 王 涛, 等). Acta Scientiae Circumstantia(环境科学学报), 2018, 38(4): 1558.
[9] JIANG Guang-jia, LIU Dian-wei, SONG Kai-shan, et al(姜广甲, 刘殿伟, 宋开山, 等). Journal of University of Chinese Academy of Sciences(中国科学院大学学报), 2009, 26(5): 640.
[10] Shang Y X, Song K S, Jacinthe P A,et al. Journal of Hydrology, 2019, 576: 1.
[11] Hu B, Wang P F, Qian J, et al. Journal of Great Lakes Research, 2017, 43: 1165.
[12] LIU Ming-liang, ZHANG Yun-lin, QIN Bo-qiang, et al(刘明亮, 张运林, 秦伯强, 等). Journal of Lake Sciences(湖泊科学), 2009, 21(2): 234.
[13] ZHANG Yun-lin, QIN Bo-qiang(张运林, 秦伯强). Advances in Water Science(水科学进展), 2007, 78(3): 415.
[14] ZHOU Lei, ZHOU Yong-qiang, ZHANG Yun-lin, et al(周 蕾, 周永强, 张运林, 等). Environmental Science(环境科学), 2021, 42(8): 3709.
[15] Rusuli Y, Li L H, Ahmad S, et al. Environmental Earth Sciences, 2015, 74 (3): 2499.
[16] Tang X M, Xie G J, Shao K Q, et al. Applied and Environmental Microbiology, 2012, 78(13): 4748.
[17] Liu Y, Mu S Y, Bao A M, et al. Environmental Earth Sciences, 2015, 73(8): 4707.
[18] Zhang L, Zhao T T, Shen T T, et al. Journal of Basic Microbiology, 2018, 59(2): 224.
[19] Mamat Z, Haximu S, Zhang Z Y, et al. Environmental Science and Pollution Research, 2016, 23(8): 7255.
[20] XU Hai-liang, CHEN Ya-ning, LI Wei-hong(徐海量, 陈亚宁, 李卫红). Journal of Arid Land Resources and Environment(干旱区资源与环境), 2003, 17(3): 95.
[21] Guo M J, Wu W, Zhou X D, et al. Theoretical and Applied Climatology, 2015, 119(1/2): 341.
[22] ZHOU Hong-hua, LI Wei-hong, CHEN Ya-ning, et al(周洪华, 李卫红, 陈亚宁, 等). Journal of Lake Sciences(湖泊科学), 2014, 26(1): 55.
[23] Zhu M Y, Zhu G W, Zhao L L, et al. Environmental Science and Pollution Research International, 2013, 20(3): 1803.
[24] LIU Xiao-han, ZHANG Yun-lin, YIN Yan, et al(刘笑菡, 张运林, 殷 燕, 等). Transactions of Oceanology and Limnology(海洋湖沼通报), 2012, 20(3): 133.
[25] Andrew A A, Del Vecchio R, Subramaniam A, et al. Marine Chemistry, 2013, 148: 33.
[26] Kothawala D N, Stedmon C A, Müller R A, et al. Global Change Biology, 2014, 20(4): 1101.
[27] Fichot C, Benner R. Limnology and Oceanography, 2012, 57(5): 1453.
[28] Murphy K R, Stedmon C A, Graeber D, et al. Analytical Methods, 2013, 5(23): 6557.
[29] Kothawala D N, Murphy K R, Stedmon C A, et al. Limnology and Oceanography: Methods, 2013, 11(12): 616.
[30] LÜ Gui-cai, ZHAO Wei-hong, WANG Jiang-tao(吕桂才,赵卫红,王江涛). Chinese Journal of Analytical Chemistry(分析化学), 2010, 38(8): 1144.
[31] WANG Rui, NIU Zhen-guo(王 瑞, 牛振国). China Environment Science(中国环境科学), 2020, 40(2): 780.
[32] Redfield A C. American Scientist, 1958, 46(3): 230A.
[33] Painter S C, Lapworth D J, Woodward E M S, et al. Science of the Total Environment, 2018, 630: 630.
[34] Romero C M, Engel R E, D’Andrilli J, et al. Geoderma, 2017, 306: 40.
[35] D’Andrilli J, Foreman C M, Sigl M, et al. Climate of the Past, 2017, 13: 533.
[36] Harjung A, Sabater F, Butturini A. Limnologica, 2018, 68: 71.
[37] Walker S A, Amon R M W, Stedmon C, et al. Journal of Geophysical Research, 2009, 114(G4):G00F06.
[38] Fouché J, Christiansen C T, Lafrenière M J, et al. Nature Communications, 2020, 11: 4500.
[39] CataláT S, Reche I, Fuentes-LemaA, et al. Nature Communications, 2016, 7(1): 12005.
[40] Murphy K R, Hambly A, Singh S, et al. Environmental Science & Technology, 2011, 45(7): 2909.
[41] SUN Zhan-dong, WANG Run(孙占东, 王 润). Journal of Lake Sciences(湖泊科学), 2006,(5): 484.
[42] GUO Dong, Tursun Kasim, ZHANG Tong-wen, et al(郭 冬, 吐尔逊·哈斯木, 张同文, 等). Desert and Oasis Meteorology(沙漠与绿洲气象), 2022, 16(1): 87.
[43] Mannino A, Russ M E, Hooker S B. Journal of Geophysical Research, 2008, 113(C7):C07051.
[44] Matsuoka A, Babin M, Doxaran D, et al. Biogeosciences, 2014, 11(12): 3131.
[45] Yu X L, Sheng F, Liu Y Y. Estuarine, Coastal and Shelf Science, 2016, 181: 302.
[46] Cao F, Tzortziou M, Hu C M, et al. Remote Sensing of Environment, 2018, 205: 151.
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