参考文献
[1] Zhao X, He X, Xi B, Gao R, Tan W, Zhang H, et al. The evolution of water extractable organic matter and its association with microbial community dynamics during municipal solid waste composting. Waste Management, 2016,56:79-87.
[2] Nakasaki K, Le T H T, Idemoto Y, Abe M, Rollon A P. Comparison of organic matter degradation and microbial community during thermophilic composting of two different types of anaerobic sludge. Bioresource Technology, 2009,100:676.
[3] Yuan Y, Tan W, He X, Xi B, Gao R, Zhang H, et al. Heterogeneity of the electron exchange capacity of kitchen waste compost-derived humic acids based on fluorescence components. Analytical & Bioanalytical Chemistry, 2016,408:1-9.
[4] He X, Xi B, Wei Z, Guo X, Li M, An D, et al. Spectroscopic characterization of water extractable organic matter during composting of municipal solid waste. Chemosphere, 2011,82:541-548.
[5] Saidpullicino D, Gigliotti G. Oxidative biodegradation of dissolved organic matter during composting. Chemosphere, 2007,68:1030-1040.
[6] Yang C, He X, Xi B, Huang C, et al. Characteristic Study of Dissolved Organic Matter for Electron Transfer Capacity During Initial Landfill Stage. Chinese Journal of Analytical Chemistry, 2016,44:1568-1574.
[7] Maurer F, Christl I, Kretzschmar R. Reduction and reoxidation of humic acid: influence on spectroscopic properties and proton binding. Environmental Science & Technology, 2010,44:5787-5792.
[8] Jokic A, Wang M C, Liu C, Frenkel A I, Huang P M. Integration of the polyphenol and Maillard reactions into a unified abiotic pathway for humification in nature. Organic Geochemistry, 2004,35:747-762.
[9] Aeschbacher M, Vergari D, Schwarzenbach R P, Sander M. Electrochemical analysis of proton and electron transfer equilibria of the reducible moieties in humic acids. Environmental Science & Technology, 2011,45:8385-8394.
[10] He X, Xi B, Cui D, Liu Y, Tan W, et al. Influence of chemical and structural evolution of dissolved organic matter on electron transfer capacity during composting. Journal of Hazardous Materials, 2014,268:256.
[11] Uchimiya M, Stone A T. Reversible redox chemistry of quinones: impact on biogeochemical cycles. Chemosphere, 2009,77:451.
[12] 须湘成, 张继宏. 不同有机物料的腐解残留率及其对土壤腐殖质组成和光学性质的影响. 土壤通报,1993:53-56.
[13] Wu J, Zhao Y, Zhao W, Yang T, et al. Effect of precursors combined with bacteria communities on the formation of humic substances during different materials composting. Bioresource Technology, 2017,226:191.
[14] Mcbeath A V, Smernik R J, Schneider M P W, Schmidt M W I, et al. Determination of the aromaticity and the degree of aromatic condensation of a thermosequence of wood charcoal using NMR. Organic Geochemistry, 2011,42:1194-1202.
[15] Gao W, Zheng G D, Gao D, Chen T B, et al. Transformation of organic matter during thermophilic composting of pig manure. Environmental Science, 2006,27:986.
[16] Zhang Y, Yue D, Ma H. Darkening mechanism and kinetics of humification process in catechol-Maillard system. Chemosphere, 2015,130:40-45.
[17] Yun Z, Yue Z, Chen Y, Qian L, Li M, et al. A regulating method for reducing nitrogen loss based on enriched ammonia-oxidizing bacteria during composting. Bioresource Technology 2016,221:276-283.
[18] Chen J, Gu B, Royer R A, Burgos W D. The roles of natural organic matter in chemical and microbial reduction of ferric iron. Science of the Total Environment 2003,307:167-78.
[19] Ratasuk N, Nanny M A. Characterization and quantification of reversible redox sites in humic substances. Environmental Science & Technology. 2007,41:7844.
[20] Said-Pullicino D, Erriquens F G, Gigliotti G. Changes in the chemical characteristics of water-extractable organic matter during composting and their influence on compost stability and maturity. Bioresource Technology, 2007,98:1822-1831.
[21] Silva M E, de Lemos L T, Nunes O C, Cunha-Queda A C. Influence of the composition of the initial mixtures on the chemical composition, physicochemical properties and humic-like substances content of composts. Waste Management, 2014,34:21.
[22] 张甲, 陶澍, 曹军. 土壤水溶性有机物与富里酸分子量分布的空间结构特征. 地理研究, 2001,20:76-82.
[23] Smilek J, Sedlek P, Kalina M, Klukov M. On the role of humic acids' carboxyl groups in the binding of charged organic compounds. Chemosphere, 2015,138:503-510.