|
|
|
|
|
|
| Composition, Distribution and Source Analysis of Dissolved Organic
Matter in the Water Body of a Typical Agricultural Watershed
in the Headwaters of Chishui River |
| LIU Shi-jie1, 2, YANG Juan2, 3*, WANG Ke-qin1 |
1. School of Soil and Water Conservation, Southwest Forestry University, Kunming 650224, China
2. Yunnan Key Laboratory of Plateau Wetland Conservation, Restoration and Ecological Services, College of Ecology and Environment, Southwest Forestry University, Kunming 650224, China
3. National Plateau Wetland Research Center, College of Ecology and Environment, Southwest Forestry University, Kunming 650224, China
|
|
|
|
|
Abstract The Chishui River serves as a crucial tributary to the upper reaches of the Yangtze River. To enhance the protection of the water ecological environment in this area, it is essential to investigate the composition characteristics and sources of dissolved organic matter (DOM) within the upstream region. This study employed UET-visible absorption spectroscopy, three-dimensional fluorescence spectroscopy (EEMs), and parallel factor analysis (PARAFAC) to investigate the composition, distribution, and source of dissolved organic matter (DOM) in the Longjing small watershed, located in the headwater area of the Chishui River (Zhenxiong Section) in northeast Yunnan Province. The findings revealed that concentrations of DOC, CDOM, and FDOM gradually increased from top to bottom within the Longjing small watershed, with DOC concentrations ranging from 4.65 to 15.35 mg·L-1, which is higher than those in other types of water bodies. Moreover, the humification degree and molecular weight level exhibited a pattern in which they decreased downstream, with lower reaches > middle reaches > upper reaches. DOM consisted of three fluorescent components: humus-like component C1, protein-like component C2, and long-wave humus component C3. Among these components, the tryptophan-based component C2 contributed significantly, accounting for 39.35% of the total fluorescence intensity, while C1 and C3 accounted for 32.17% and 28.48%, respectively.The origin of DOM primarily stemmed from autogenesis, characterized by weak humification; however, there was also some influence from both internal and external sources on certain sections within the Longjing small watershed due to comprehensive load effects.Under conditions such as isohigh reverse slope terrain, combined with nitrogen/phosphorus accumulation and vigorous microbial activity, DOM generation was promoted, altering its molecular structure.The C1 and C3 components exhibited a highly significant positive correlation, indicating their homology. TN and TP also demonstrated a significant positive correlation with the C1 and C3 components. Nitrogen and phosphorus in the Longjing small watershed predominantly existed in the form of organic nitrogen and organophosphorus, which combined with humus to contribute to exogenous DOM. This study provides valuable insights into the water quality of the Yangtze River's source waters, offering guidance for protecting its aquatic environment.
|
|
Received: 2024-06-28
Accepted: 2024-12-14
|
|
|
|
Corresponding Authors:
YANG Juan
E-mail: kittyyangjuan@swfu.edu.cn;phdyangjuan@foxmail.com
|
|
[1] Gu N, Song Q, Yang X, et al. Environmental Pollution, 2020, 258: 113807.
[2] Liu D, Du Y, Yu S, et al. Water Research, 2020, 168: 115132.
[3] Song K, Li L, Tedesco L, et al. Chinese Geographical Science, 2015, 25(3): 295.
[4] LI Hai-bin, XIE Fa-zhi, LI Guo-lian, et al(李海斌, 谢发之, 李国莲, 等). China Environmental Science(中国环境科学), 2022, 42(7): 3306.
[5] Chen M, Jung J, Lee Y K, et al. Science of the Total Environment, 2018, 639: 624.
[6] QIN Ji-hong, WANG Shu, LIU Chen, et al(秦纪洪, 王 姝, 刘 琛, 等). China Environmental Science(中国环境科学), 2019, 39(10): 4321.
[7] NI Mao-fei, ZHOU Hui, MA Yong-mei, et al(倪茂飞, 周 慧, 马永梅, 等). Environmental Science(环境科学), 2022, 43(7): 3552.
[8] Liu Shasha, Zhao Tianhui, Zhu Yuanrong, et al. Scienceof the Total Environment, 2018, 616: 602.
[9] HE Wei, BAI Ze-lin, LI Yi-long, et al(何 伟, 白泽琳, 李一龙, 等). Acta Scientiae Circumstantiae(环境科学学报), 2016, 36(2): 359.
[10] 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.
[11] WANG Qi-lei, JIANG Tao, ZHAO Zheng, et al(王齐磊, 江 韬, 赵 铮, 等). Environmental Science(环境科学), 2015, 36(3): 879.
[12] ZHU Peng, HUA Zu-lin, ZHANG Run-yu, et al(祝 鹏, 华祖林, 张润宇, 等). Research of Environmental Sciences(环境科学研究), 2010, 23(2): 129.
[13] Rochelle-Newall E J, Fisher T R. Marine Chemistry, 2002, 77(1): 23.
[14] Williams C J, Yamashita Y, Wilson H F, et al. Limnology and Oceanography, 2010, 55(3): 1159.
[15] Helms J R, Stubbins A, Ritchie J D, et al. Limnology and Oceanography, 2008, 53(3): 955.
[16] Vignudelli S, Santinelli C, Murru E, et al. Estuarine, Coastal and Shelf Science, 2004, 60(1): 133.
[17] Wickland K P, Neff J C, Aiken G R. Ecosystems, 2007, 10(8): 1323.
[18] Zhou Y, Zhang Y, Shi K, et al. Journal of Great Lakes Research, 2015, 41(2): 597.
[19] Zhang Y L, Qin B Q, Chen W M, et al. Acta Hydrochimica et Hydrobiologica, 2005, 33(4): 315.
[20] LIU Dan, TIAN Chan-juan, CHEN Xue-qun, et al(刘 丹, 田婵娟, 陈学群, 等). Carsologica Sinica(中国岩溶), 2024, 43(3): 500.
[21] Helms J R, Stubbins A, Perdue E M, et al. Marine Chemistry, 2013, 155: 81.
[22] MA Zhuo-ni, GUO Chun-zi, ZHANG Hao, et al(马卓妮, 郭纯子, 张 浩, 等). Environmental Science(环境科学), 2025, 46(3): 1395.
[23] HE Lin-dong, WU Yong, LI Hong-tao, et al(何林东, 吴 勇, 李洪涛, 等). Ground Water(地下水), 2024, 46(5): 123.
[24] YANG Yi, DONG Cheng-xuan, ZHU Yu-qiang, et al(杨 毅,董承璇,朱裕强,等). China Environmental Science(中国环境科学), 2024, 44(2): 953.
[25] WANG Shuang, WANG San-xiu, HUANG Qing-hui(王 爽, 王三秀, 黄清辉). Acta Scientiae Circumstantiae(环境科学学报), 2022, 42(11): 139.
[26] McKnight D M, Boger E W, Westerhoff P K, et al. Limnology and Oceanography, 2001, 46(1): 38.
[27] LIU Rui-xia, LI Bin, LIU Na-na, et al(刘瑞霞, 李 斌, 刘娜娜, 等). Acta Scientiae Circumstantiae(环境科学学报), 2014, 34(9): 2321.
[28] Mu G Y, Ji M C, Li S J. Environmental Science and Pollution Research, 2018, 25: 27545.
|
| [1] |
YANG Fu-qin1, LI Chang-hao1, ZHANG Ying-fa1, CHEN Ri-qiang2, LIU Yang2, GUO Liang-dong3, FENG Hai-kuan2, 4*. Remote Sensing Monitoring of Nitrogen Nutrient Index in Winter Wheat by Integrating Hyperspectral and Digital Imagery[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2025, 45(06): 1719-1728. |
| [2] |
YANG Fu-qin1, CHEN Ri-qiang2, LIU Yang2, CHEN Xin-xin1, XIAO Yi-bo1, LI Chang-hao1, WANG Ping3, FENG Hai-kuan2, 4*. Monitoring Potato Biomass and Plant Nitrogen Content With UAV-Based Hyperspectral Imaging[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2025, 45(06): 1729-1738. |
| [3] |
LI Huan-tong1, ZOU Xiao-yan2, ZHANG Ting-ting1, ZHANG Wei-guo1, WANG Jun-qi1. Uneven Distribution and Transformation of Nitrogens During Vitrinite- and Inertinite-Rich Coal Pyrolysis Char of Xiaobaodang Coal Mining
Area, Northern Shaanxi Province[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2025, 45(05): 1494-1500. |
| [4] |
DONG Yi-fan, AI Qiu-shuang, YU Xi-ren, ZHANG Li, LIANG Jing-tian, ZHANG Da-wen, QIU Su-yan*. Construction of Manganese Doped ZnS Quantum Dots Phosphorescence System and Its Application to Pb(Ⅱ) Sensing Detection[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2025, 45(04): 964-970. |
| [5] |
QIAN Xue-wen1, LIU Xian-yu1, 2, 3*, LI Jing-jing1, YUAN Ye4. Study on the Vibrational Spectra of Pyromorphite From Guilin of Guangxi Province[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2025, 45(03): 735-741. |
| [6] |
ZHANG Guo-hao1, WANG Cai-ling1*, WANG Hong-wei2*, YU Tao3. Improved Particle Swarm Optimization Algorithm Combined With BP Neural Network Model for Prediction of Total Phosphorus Concentration in Water Body Using Transmittance Spectral Data[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2025, 45(02): 394-402. |
| [7] |
LIANG Xing-hui1, 2, 3, FENG Wei-wei1, 2, 3*, CAI Zong-qi1, 2, WANG Huan-qing1, 2, YANG Jian-lian1, 2, 3. Measurement Method of Nitrate and Nitrite in Seawater Based on First-Order Differential Spectrum[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2025, 45(01): 45-51. |
| [8] |
YANG Guang1, PAN Hong-wei1*, TONG Wen-bin1, WANG Ke-ke2, CHEN Hui-ru1, WANG Yi-fei1, KONG Hai-kang1, WANG Xiao-wan1, LEI Hong-jun1*. The Impact of Applying Chicken Manure on Nutrient Release From Wheat Straw and the Evolution of Dissolved Organic Matter in Soil[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(11): 3186-3194. |
| [9] |
LU Ming-mei1, ZHOU Zheng-yu1, 2, 3*, QI Li-jian1, 2, 3, LIU Zi-qi1, CHEN Yi-fang1, ZHENG Jun-hao1. Study on Spectral Characteristics and Differences of Natural and Pink Dushan Jade[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(11): 3157-3164. |
| [10] |
ZHANG Jia-wei1, WU Dong-sheng1, ZHOU Yang2, LI Yang2, 3, 4, SUN Lan-xiang2, 3, 4*. Study on the Influence of Argon Environment on the Determination of C, P and S Elements in Steel by Laser-Induced Breakdown Spectrometry[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(10): 2834-2839. |
| [11] |
QIN Jing, WANG Ke-dong, HU Xue-fang, CHEN Xiao-yuan, LIU Chao. Effect of Pericyclic Substitutes on the Spectral Properties of
Phthalocyanine in Different Substrates[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(10): 2953-2958. |
| [12] |
LI Hong-yu1, 2, 3, GAO Zheng-wu1, 2, 3, WANG Zhi-jun4, LIN Tian1, 2, 3, ZHAO Hai-cheng1, 2, 3, FAN Ming-yu1, 2, 3. Prediction of Leaf Nitrogen Content of Rice in Cold Region Based on Spectral Reflectance[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(09): 2582-2593. |
| [13] |
WANG Hao-yu1, 2, 3, WEI Zi-yuan1, 2, 3, YANG Yong-xia1, 2, 3, HOU Jun-ying1, 2, 3, SUN Zhang-tong1, 2, 3, HU Jin1, 2, 3*. Estimation of Eggplant Leaf Nitrogen Content Based on Hyperspectral Imaging and Convolutional Auto-Encoders Networks[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(08): 2208-2215. |
| [14] |
SONG Yu1, 2, LI Wei-hua1, 2*, XUE Tong-zhan1, 2, YU Li1, 2, SHEN Hui-yan1, 2. Spectral Feature Band Selection and Interval Partial Least Squares
Modeling of Short-Range Nitrification Process[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(08): 2224-2232. |
| [15] |
ZHANG Xiu-quan1, MA Shi-xing1, LI Zhi-wei2*, ZHENG De-cong1, SONG Hai-yan1. Prediction of Total Nitrogen Content in Brown Soil Based on Hyperspectral and Combined Prediction Model[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(08): 2310-2317. |
|
|
|
|
