Molecular weight fractionated characterization of dissolved organic matter and its correlation with water quality in the Bahe River Basin, Northwest China

doi:10.13287/j.1001-9332.201811.015

Abstract

Abstract: Dissolved organic matter (DOM) is one of the core carriers of organic matter decomposition and nutrient regeneration in water. It is an important link of biogeochemical cycle of carbon and nitrogen, and the key content of water environmental science research. We used liquid chromatography-organic carbon detection-organic nitrogen detection (LC-OCD-OND) to investigate the molecular weight distribution of riverine DOM in the Bahe River of Xi’an City and further analyzed its correlation with water quality. The results showed that riverine DOM was composed of biopolymers, humic substances, humus degradation products, and low molecular-weight neutrals, with the ave-rage concentration of 0.15, 1.75, 0.48, 0.36 and 0.002 mg·L^-1, respectively. The DOM along the river was in order of urban＞ town＞ river source. The humic substances with molecular weight of 1000-20000 Da accounted for 49.0% of total DOM which followed the order of town＞ waste water treatment plants (WWTPs) effluents＞river estuary＞ river source. The biopolymers with the molecular weight of >20000Da accounted for 5.1% of total DOM, with the sequence of WWTPs effluents＞river estuary＞river source＞town. The allochthonous (terrigenous) DOM produced by WWTPs effluents had the greatest contribution to the riverine DOM. The fractions of DOM with different molecular weights had significant correlations with water quality parameters. The results showed that the molecular weight fractions and abundance of DOM based on LC-OCD-OND could be used as a comprehensive index for water quality monitoring, to characterize the spatial heterogeneity of river water quality, and used for quantitative identification and source apportionment of pollutant components.

YUAN Bo, GUO Meng-jing, ZHENG Xing, ZHOU Xiao-de. Molecular weight fractionated characterization of dissolved organic matter and its correlation with water quality in the Bahe River Basin, Northwest China[J]. Chinese Journal of Applied Ecology, 2018, 29(11): 3773-3782.

References

[1] Aiken GR, Hsu-Kim H, Ryan JN. Influence of dissolved organic matter on the environmental fate of metals, nanoparticles, and colloids. Environmental Science & Technology, 2011, 45: 3196-3201
[2] He W, Chen ML, Schlautman MA, et al. Dynamic exchanges between DOM and POM pools in coastal and inland aquatic ecosystems: A review. Science of the Total Environment, 2016, 551/552: 415-428
[3] Hur J, Lee BM. Characterization of binding site heterogeneity for copper within dissolved organic matter fractions using two-dimensional correlation fluorescence spectroscopy. Chemosphere, 2011, 83: 1603-1611
[4] Xu HC, Yu GH, Yang LY, et al. Combination of two-dimensional correlation spectroscopy and parallel factor analysis to characterize the binding of heavy metals with DOM in lake sediments. Journal of Hazardous Mate-rials, 2013, 263: 412-421
[5] Stolpe B, Guo LD, Shiller AM, et al. Size and composition of colloidalorganic matter and trace elements in the Mississippi River, Pearl River and the northern Gulf of Mexico, as characterized by flow field-flow fractionation. Marine Chemistry, 2010, 118: 119-128
[6] Nebbioso A, Piccolo A. Molecular characterization of dissolved organic matter (DOM): A critical review. Analytical and Bioanalytical Chemistry, 2013, 405: 109-124
[7] Mangal V, Stock NL, Gueguen C. Molecular characte-rization of phytoplankton dissolved organic matter (DOM) and sulfur components using high resolution Orbitrap mass spectrometry. Analytical and Bioanalytical Chemistry, 2016, 408: 1891-1900
[8] Piccolo A, Conte P, Trivellone E, et al. Reduced hete-rogeneity of a lignite humic acid by preparative HPSEC following interaction with an organic acid. Characterization of size-separates by Pyr-GC-MS and 1H-NMR spectroscopy. Environmental Science and Technology, 2002, 36: 76-84
[9] Chon KM, Chon K, Cho J. Characterization of size fractionated dissolved organic matter from river water and wastewater effluent using preparative high performance size exclusion chromatography. Organic Geochemistry, 2017, 103: 105-112
[10] Ma H, Allen HE, Yin Y. Characterization of isolated fractions of dissolved organic matter from natural waters and a wastewater effluent. Water Research, 2001, 35: 985-996
[11] Maurice PA, Pullin MJ, Cabaniss SE, et al. A comparison of surface water natural organic matter in raw filtered water samples, XAD, and reverse osmosis isolates. Water Research, 2002, 36: 2357-2371
[12] Kim S, Simpson AJ, Kujawinski EB, et al. High resolution electrospray ionization mass spectrometry and 2D solution NMR for the analysis of DOM extracted by C18 solid phase disk. Organic Geochemistry, 2003, 34: 1325-1335
[13] Schwede-Thomas SB, Chin YP, Dria K, et al. Characterizing the properties of dissolved organic matter isolated by XAD and C18 solid phase extraction and ultrafiltration. Aquatic Science, 2005, 67: 61-71
[14] Croué JP. Isolation of humic and non-humic NOM fractions: Structural characterization. Environmental Monitoring and Assessment, 2004, 92: 193-207
[15] Williams JS, Dungait JAJ, Bol R, et al. Comparison of extraction efficiencies for water-transportable phenols from different land uses. Organic Geochemistry, 2016, 102: 45-51
[16] Wu FC, Evans RD, Dillon PJ, et al. Rapid quantification of humic and fulvic acids by HPLC in natural waters. Applied Geochemistry, 2007, 22: 1598-1605
[17] Peuravuori J, Pihlaja K. Preliminary study of lake dissolved organic matter in light of nanoscale supramolecular assembly. Environmental Science and Technology, 2004, 38: 5958-5967
[18] Huber SA, Balz A, Abert M, et al. Characterisation of aquatic humic and non-humic matter with size-exclusion chromatography-organic carbon detection-organic nitrogen detection (LC-OCD-OND). Water Research, 2011, 45: 879-885
[19] Jacquin C, Lesage G, Traber J, et al. Three-dimensional excitation and emission matrix fluorescence (3DEEM) for quick and pseudo-quantitative determination of protein and humic-like substances in full-scale membrane bioreactor (MBR). Water Research, 2017, 118: 82-92
[20] Velten S, Knappe DRU, Traber J, et al. Characterization of natural organic matter adsorption in granular activated carbon adsorbers. Water Research, 2011, 45: 3951-3959
[21] Rachman RM, Li S, Missimer TM. SWRO feed water quality improvement using subsurface intakes in Oman, Spain, Turks and Caicos Islands, and Saudi Arabia. Desalination, 2014, 351: 88-100
[22] Baghoth SA, Sharma SK, Guitard M, et al. Removal of NOM-constituents as characterized by LC-OCD and F-EEM during drinking water treatment. Journal of Water Supply: Research and Technology, 2011, 60: 412-424
[23] Zhang Y, van Dijk MA, Liu M, et al. The contribution of phytoplankton degradation to chromophoric dissolved organic matter (CDOM) in eutrophic shallow lakes: Field and experimental evidence. Water Research, 2009, 43: 4685-4697
[24] Zhang YL, Zhang EL, Yin Y, et al. Characteristics and sources of chromophoric dissolved organic matter in lakes of the Yungui Plateau, China, differing in trophic state and altitude. Limnology and Oceanography, 2010, 55: 2645-2659
[25] Hu S (胡胜), Cao M-M (曹明明), Qiu H-J (邱海军), et al. Applicability evaluation of CFSR climate data for hydrologic simulation: A case study in the Bahe River Basin. Acta Geologica Sinica (地理学报), 2016, 71(9): 1571-1586 (in Chinese)
[26] State Environmental Protection Administration of China (国家环境保护局). Monitoring Method for Water and Wastewater. 4th Ed. Beijing: China Environmental Science Press, 2002 (in Chinese)
[27] Egeberg PK, Alberts JJ. HPSEC as a preparative fractionation technique for studies of natural organic matter (NOM). Environmental Technology, 2003, 24: 309-318
[28] Allpike BP, Heitz A, Joll CA, et al. Size exclusion chromatography to characterize DOC removal in drin-king water treatment. Environmental Technology, 2005, 39: 2334-2342
[29] Zhang Y (张远), Zhang Y (张彦), Yu T (于涛), et al. Contribution rate of exogenous organic matter in sediments from typical areas of Taihu Lake. Research of Environmental Sciences (环境科学研究), 2011, 24(3): 251-258 (in Chinese)
[30] Xie X-F (谢秀风), Xi M (郗敏), Li Y (李悦), et al. Research of the source identification methods for dissolved organic matter (DOM) in wetland. Geological Review (地质论评), 2014, 60(5): 1102-1108 (in Chinese)
[31] McKnight DM, Andrews ED, Spaulding SA, et al. Aquatic fulvic acids in algal-rich Antarctic ponds. Limnology and Oceanography, 1994, 39: 1972-1979
[32] Earn H, Williams WW, McKnight DM. Sources of dissolved organic matter (DOM) in a rocky mountain stream using chemical fractionation and stable isotopes. Biogeochemistry, 2005, 74: 231-255
[33] Liu Q (刘琦), Jiang Y (江源), Ding J (丁佼), et al. Exploring the pollution characteristics of dissolved organic matter in the primary tributaries of the Dongjiang River. Journal of Natural Resources (自然资源学报), 2016, 31(7): 1231-1240 (in Chinese)
[34] Yu H-B (于会彬), Song Y-H (宋永会), Yang N (杨楠), et al. Characterizing structural composition of dissolved and particulate organic matter from sediment pore water in a urban river using excitation-emission matrix fluorescence with self-organizing map. Spectroscopy and Spectral Analysis (光谱与光谱学分析), 2015, 35(4): 934-939 (in Chinese)
[35] Baker A. Fluorescence excitation-emission matrix cha-racterization of some sewage-impacted rivers. Environmental Science & Technology, 2001, 35: 948-953
[36] Gan S-C (甘淑钗), Wu Y (吴莹), Bao H-Y (鲍红艳), et al. Characterization of DOM (dissolved organic matter) in Yangtze River using 3-D fluorescence spectroscopy and parallel factor analysis. China Envi-ronmental Science (中国环境科学), 2013, 33(6): 1045-1052 (in Chinese)
[37] Liu R-X (刘瑞霞), Li B (李斌), Liu N-N (刘娜娜), et al. Fluorescence characteristics of dissolved organic matter in freshwaters from Liaohe Basin and Midland of UK. Acta Scientiae Circumstantiae (环境科学学报), 2014, 34(9): 2321-2328 (in Chinese)