Abstract:It has been acknowledged by WHO that styrene is a carcinogen which does great harm to human’s health and natural environment. In recent years, given the frequency of the leakage accidents of styrene that has given rise to potential safety hazard to drinking water, the fast detection of styrene pollutant in water and treatment of accidental release are of great significance for supplying safe drinking water. Total scanning fluorescence technique was used to unravel the 3D fluorescence feature of styrene by scanning its aqueous solution. A distinct fluorescence peak of styrene located at Ex255/Em305 was detected. There was a significant linear correlation between the concentration of styrene and the value of fluorescence peak, the correlation index being 0.995 7. The color of the fluorescence peak got darker with the raise of styrene concentration. There were four conjugated double bonds existing in the structure of styrene, among which a cyclic hydrocarbon with a continuous pi bond exists in benzene ring, the other one is in vinyl. All carbon atoms that makes up the structure of styrene were in the same plane, thus styrene molecules were completely planar with certain rigidity, which is the feature of fluorescent substances. Therefore, the concentration of styrene and the pollution of water by the leakage of styrene could be easily detected with the 3D fluorescence spectra. Powdered activated carbon (PAC) had a good effect on the absorption of styrene dissolved in water. Adding PAC(180 mesh) at a dosage of 15 mg·L-1 into source water with the concentration of styrene was 0.02 mg·L-1, which is the limited value in sanitary standard for drinking water, the concentration could be reduced to 0.001 mg·L-1 and the removal rate of styrene was as high as 95.5% .
周 昀,李 军*,陈 飞,马 挺,倪永炯 . 苯乙烯的三维荧光特性及水污染应急处理 [J]. 光谱学与光谱分析, 2016, 36(07): 2169-2172.
ZHOU Yun, LI Jun*, CHEN Fei, MA Ting, NI Yong-jiong . Study on the 3D Fluorescence Feature of Styrene and Emergent Treatment of Styrene Pollutant in Water . SPECTROSCOPY AND SPECTRAL ANALYSIS, 2016, 36(07): 2169-2172.
[1] LI Tan-ping, WANG Zeng-zhang, BAI Xiao-hui, et al(李探平, 王增长, 白晓慧, 等). China Water & Wastewater(中国给水排水), 2014, (13): 6. [2] FENG Yi-zhen, QU Chun(冯亦珍,瞿 春). Safety: Healthy and Environment(安全: 健康与环境), 2001, (12): 10. [3] LIN Hong, HU Ping, WU Xian-hua(林 洪, 胡 平, 吴献花). Journal of Yuxi Normal University(玉溪师范学院学报), 2005, (3): 17. [4] LI Hong-bin, LIU Wen-qing, ZHANG Yu-jun(李宏斌, 刘文清, 张玉钧). Optical Technique(光学技术), 2006, 01: 27. [5] XIE Zhi-gang, JI Fang-ying, HUANG He(谢志刚, 吉芳英, 黄 鹤). China Water & Wastewater(中国给水排水), 2009, 15: 103. [6] Baker A, Curry M. Water Research, 2004, 38(10): 2605. [7] LIAO Hong-ri, ZHAN Nan, SHEN Ying-jie(廖红日, 战 楠, 申颖洁). China Water & Wastewater(中国给水排水), 2011, 01: 92. [8] SHEN Ying-jie, LIAO Ri-hong, ZHAN Nan, et al(申颖洁, 廖日红, 战 楠, 等) . Chinese Journal of Environmental Engineering(环境工程学报) , 2013 , 01: 125. [9] Hur J, Hwang S J, Shin J K. Water Air and Soil Pollution, 2008, 191(1-4): 231. [10] JIANG Jian-fei, CHEN Kun(姜剑飞, 陈 琨). Heilongjiang Science and Technology of Water Conservancy(黑龙江水利科技), 2009, (4): 76. [11] WANG Jian-ping, HUANG Chang-jun(王建平, 黄长均). China Water & Wastewater(中国给水排水), 2006, (10): 17. [12] Shao Z H, He P J, Zhang D Q, et al. Journal of Hazardous Materials, 2009, 164(2): 1191. [13] ZHEN Xiao-ying, WANG Jian-long, LI Xin-wei(郑晓英, 王俭龙, 李鑫玮). China Environmental Science(中国环境科学), 2014, (5): 1159. [14] Baker A. Water Research, 2002, 36(1): 189. [15] XU Jin-gou, WANG Zun-ben(许金钩, 王尊本). Fluoreseence Analysis Method(荧光分析法). Beijing: Science Press(北京:科学出版社), 2006. 21.
