Ozonation characteristics of low coagulability organics based on two dimensional correlation analysis
JIN Xin1, HOU Rui1, SONG Ji-na1,2, JIN Peng-kang1, WANG Xiao-chang1
1. Department of Environmental and Municipal Engineering, Xi'an University of Architecture and Technology, Xi'an 710055, China; 2. College of Energy and Environmental Engineering, Hebei University of Engineering, Handan 056038, China
Abstract:Based on two dimensional correlation analysis,the characteristics of low coagulability organic matters from WWTP effluent during ozonation were studied.The results showed that coagulation can hardly remove dissolved organic matters in WWTP effluent,and most of dissolved organic matters in WWTP effluent belonged to low coagulability organic matters,which mainly contained humic-like substances.Color and UV254 of coagulated supernatant can be removed by ozonation with removal efficiency higher than 70% and 40% respectively.However,the removal efficiency of low coagulability organic matters was low (lower than 10% removal efficiency) indicating the organic matter characteristics variation caused by ozonation.Furthermore,the fluorescence intensity could be reduced by ozonation,and the fluorescence intensity of humic-like substances exhibited highest decrease.According to the results of synchronous fluorescence spectra at different ozone dosages,two dimensional correlation spectra can be obtained.The results indicated that humic-like substances were most sensitive fractions to ozonation in low coagulability organics from WWTP,and ozone would preferentially react with humic-like substances rather than fulvic-like substances.
金鑫, 侯瑞, 宋吉娜, 金鹏康, 王晓昌. 基于2D-COS分析的难凝聚有机物臭氧化特性研究[J]. 中国环境科学, 2018, 38(3): 923-928.
JIN Xin, HOU Rui, SONG Ji-na, JIN Peng-kang, WANG Xiao-chang. Ozonation characteristics of low coagulability organics based on two dimensional correlation analysis. CHINA ENVIRONMENTAL SCIENCECE, 2018, 38(3): 923-928.
Jin P K, Jin X, Wang X C, et al. An analysis of the chemical safety of secondary effluent of reuse purposes and the requirement for advanced treatment[J]. Chemosphere, 2013,91(4):558-562.
Wang Z G, Cao J, Meng F G. Interactions between protein-like and humic-like components in dissolved organic matter revealed by fluorescence quenching[J]. Water Res., 2015,68:404-413.
[8]
Jin P K, Jin X, Bjerkelund V A, et al. A study on the reactivity characteristics of dissolved effluent organic matter (EfOM) from municipal wastewater treatment plant during ozonation[J]. Water Res., 2016,88:643-652.
[9]
Noda I. Two-dimensional infrared (2-D IR) spectroscopy of synthetic and biopolymers[J]. B. Am. Meteorol. Soc., 1986, 31(3):520.
[10]
Noda I, Dowrey A E, Marcott C. Recent developments in two-dimensional infrared correlation spectroscopy[J]. Appl. Spectrosc., 1993,47(9):1317-1323.
[11]
Zheng X, Ernst M, Jekel M. Identification and quantification of major organic foulants in treated domestic wastewater affecting filterability in dead-end ultrafiltration[J]. Water Res., 2009,43(1):238-244.
[12]
Xu X, Li J, Xu N, et al. Visualization of fouling and diffusion behaviors during hollow fiber microfiltration of oily wastewater by ultrasonic reflectometry and wavelet analysis[J]. J. Membrane Sci., 2009,341(1/2):195-202.
[13]
Spettmann D, Eppmann S, Flemming H C, et al. Visualization of membrane cleaning using confocal laser scanning microscopy[J]. Desalination, 2008,224(1-3):195-200.
[14]
Yu G H, Wu M J, Wei G R, et al. Binding of Organic Ligands with Al(Ⅲ) in Dissolved Organic Matter from Soil:Implications for Soil Organic Carbon Storage[J]. Environ. Sci. Technol., 2012, 46:6102-6109.
[15]
Chen W, Qian C, Liu X Y, et al. Two-Dimensional correlation spectroscopic analysis on the interaction between humic acids and TiO2 nanoparticles[J]. Environ. Sci. Technol., 2014,48:11119-11126.
[16]
Chen W, Habibul N, Liu X Y, et al. FTIR and Synchronous Fluorescence Heterospectral Two Dimensional Correlation Analyses on the Binding Characteristics of Copper onto Dissolved Organic Matter[J]. Environ. Sci. Technol., 2015,49:2052-2058.
[17]
Noda I. Close-up view on the inner workings of two-dimensional correlation spectroscopy[J]. Vib. Spectrosc., 2012,60:146-153.
[18]
曾凡亮,罗先桃.分光光度法测定水样的色度[J]. 工业水处理, 2006,26(9):69-72.
[19]
Hur J, Jung K Y, Jung Y M. Characterization of spectral responses of humic substances upon UV irradiation using two-dimensional correlation spectroscopy[J]. Water Res., 2011,45(9):2965-2974.
[20]
Noda I. Generalized two-dimensional correlation method applicable to infrared, raman, and other types of spectroscopy[J]. Appl. Spectrosc., 1993,47(9):1329-1336.