光谱学与光谱分析 |
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Simultaneous Determination of Phenol and Aniline in Waste Water by Absorbance Ratio Derivative Method |
NI Yong-nian, ZHOU Xiao-qun, QIU Ping |
Department of Chemistry, Nanchang University, Nanchang 330047, China |
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Abstract A method of simultaneous determination of phenol and aniline in waste water by absorbance ratio derivative is reported in this paper. The sample, with which the pretreatment steps such as extraction, distillation, color development, and acid addition were not needed, was directly determined by the proposed method. Several synthetic samples of phenol and aniline and some real samples of waste water were determined by the method and satisfactory results were obtained. Under the optimal experimental conditions, the linear ranges of determination are 1.01-24.24 mg·L-1 for phenol and 1.01-24.29 mg·L-1 for aniline. And the limits of detection are 0.097 mg·L-1 for phenol and 0.685 mg·L-1 for aniline. For synthetic mixtures, the relative standard derivations (RSD) are less than 2.60% for both phenol and aniline, and the recovery is in the range of 95%-104%, but for real water samples the recovery is in the range of 91%-108%. The proposed method features high sensitivity and rapid resolution.
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Received: 2002-10-11
Accepted: 2003-03-01
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Corresponding Authors:
NI Yong-nian
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Cite this article: |
NI Yong-nian,ZHOU Xiao-qun,QIU Ping. Simultaneous Determination of Phenol and Aniline in Waste Water by Absorbance Ratio Derivative Method [J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2004, 24(01): 118-121.
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URL: |
http://www.gpxygpfx.com/EN/Y2004/V24/I01/118 |
[1] Talsky G. Intern. J Environ. Anal. Chem., 1983, 14(2): 81. [2] 抚顺石油研究所污水研究室. 炼油厂污水水质分析方法. 北京:石油工业出版社, 1990. [3] CHEN Shu-yu, LIN Shu-qin, LIU Li-qi(陈树榆,林淑钦,刘理奇). Physical Testing and Chemical Analysis, Part B: Chemical Analysis (理化检验-化学分册), 1986, 22(5): 293. [4] WANG Lin(王 林). J. Petroleum University, Natrual Science (石油大学学报自然科学版), 1990, 14(3): 192. [5] LI Ping, ZHAO Shan-lin, ZHANG Ming et al(李 萍,赵杉林,张 明等). Petrochemical Technology(石油化工), 1994, 23(4): 263. [6] LI Ping, ZHAO Shan-lin, ZHANG Jin-hui(李 萍,赵杉林,张金辉). J. Fushun Institute of Petroleum(抚顺石油学院学报), 2002, 22(3):29. [7] ZHAO Shan-lin, LI Ping, XIAO Guang et al(赵杉林,李 萍, 肖 光等). Physical Testing and Chemical Analysis, Part B: Chemical Analysis (理化检验-化学分册), 1998, 34(9):395. [8] NI Yong-nian, PENG Fu-de(倪永年,彭伏德). Chinese J. of Analytical Chemistry (分析化学), 1996, 24(3): 249. [9] Miller J N. Analyst, 1991, 116: 3. [10] 水质分析大全编委会. 水质分析大全. 重庆:科学技术文献出版社,1989. |
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