1. School of Resources and Environmental Engineering, Wuhan University of Technology, Wuhan 430070, China 2. Center for Materials Research and Analysis, Wuhan University of Technology, Wuhan 430070, China
Abstract:The adsorption of pentachlorophenol on hematite was studied through adsorption experiments and FTIR analysis. The pH adsorption isotherms of pentachlorophenol onto hematite were obtained by the static state experiments. The largest adsorption quantity occurred at about pH 6. The adsorption quantity at pH 8.5 of the isoelectric point of hematite was about 31% of the largest adsorption quantity. Fourier transform infrared (FTIR) spectroscopy was used to analyse the change of hematite before and after PCP adsorption, and the species of PCP on hematite. It was discovered that: (1) the typical peak at 565 cm-1 of the Fe—O bond in α-Fe2O3 did not change before and after adsorption, and the adsorption occurred on the surface of hematite. (2) At pH 6.0, the stretching vibration peak at 3 438 cm-1 due to the hydrogen bond formed between O—H on the surface of α-Fe2O3 and water molecules shifted to 3 417 cm-1. The bending vibration peak of H—O—H+ on the surface at 1 643 cm-1 was weakened because of complex reaction. The peak owing to Fe—OH bond was displaced from 1 050-1 100 cm-1 to 950 cm-1 with increased intensity. The C—O bond stretching vibration peak of PCP was displaced from 1 215 to 1 122 cm-1. The main interaction between PCP and hematite was static electric interaction. (3) At pH 8.5, the stretching vibration peak of the hydrogen bond formed between O—H on the surface of α-Fe2O3 and water molecules was displaced from 3 438 to 3 428 cm-1. The bending vibration peak at 1 643 cm-1 was obviously weakened because of the hydrogen bonding. The H—O—H+ bending vibration peak at 1 050-1 100 cm-1 was displaced to 947 cm-1 with obviously increased intensity, indicating that the interaction was mainly through hydrogen bond.
[1] Ocomell J E, Fox P F. International Dairy Journal,2001,11(3): 103. [2] Hileman B. Chem. Eng. News,1993,71(16): 11. [3] Lee C C,Huffman G L. Environ. Prog., 1989, 28: 14. [4] Stuart S L, Woods S L, Lemmon T L. Biotechnology and Bioengineering, 1999, 63(1): 69. [5] Tuomela M, Lyytikainen M, Oivanen P, et al. Soil Biology and Biochemistry, 1999, 31(1): 65. [6] Stumm W, Sulzberger B. Geochim. et Comochimica Acta, 1992, 56(8): 3233. [7] SUN Zhen-ya, DU Jian-hua, CHEN He-sheng, et al(孙振亚,杜建华,陈和生,等). Spectroscopy and Spectral Analysis(光谱学与光谱分析),2006,26(7): 1226. [8] WU Da-qing, DIAO Gui-yi, YUAN Peng, et al(吴大清,刁桂仪,袁 鹏,等). Geochimica(地球化学),2005,34(3): 31. [9] Ruan H D, Frost R L, Kloprgge J T, et al. Spectrochimica,Acta Part A, 2002, 58: 967. [10] Schindier p W. Co Adsorption of Metal Ions and Organic Ligands: Formation of Ternary Surface Complexes. Hochella Jr M F,White A F. Mineral-Water Interface Geochemi-Stry. Washington DC: Min. Society of Am.,1990. 281. [11] Koretsky C M,Sverjensky D A,Sahai N. Am. J. Sci.,1998,298(5): 349. [12] OUYANG Tian-zhi, ZHAO Zhen-hua, GU Xiao-man, et al(欧阳天贽, 赵振华, 顾小曼, 等). Spectroscopy and Spectral Analysis(光谱学与光谱分析),2003,23(6): 1097. [13] FENG Jin-cheng(冯金诚). Analysis and Appraisal of Organic Compound Structure(有机化合物结构分析与鉴定). Beijing: National Defence Industry Press(北京:国防工业出版社), 2003. 16. [14] XUE Song(薛 松). Organic Structure Analysis(有机结构分析). Hefei: University of Science and Technology of China Press(合肥:中国科学技术大学出版社),2005. 288.
