ﻣﺠﻠﻪ ﺳﻼﻣﺖ و ﻣﺤﯿﻂ ﻓﺼﻠﻨﺎﻣﻪ ي ﻋﻠﻤﯽ ﭘﮋوﻫﺸﯽ اﻧﺠﻤﻦ ﻋﻠﻤﯽ ﺑﻬﺪاﺷﺖ ﻣﺤﯿﻂ اﯾﺮان ﻋﻤﺎد دﻫﻘﺎﻧﯽ ﻓﺮد 1 اﺣﻤﺪ ﺟﻨﯿﺪي ﺟﻌﻔﺮي 2 روﺷﻨﮏ رﺿﺎﯾﯽ ﮐﻼﻧﺘﺮي 3 ﻣﯿﺘﺮا ﻏﻼﻣﯽ 4 ﻋﻠﯽ اﺳﺮاﻓﯿﻠﯽ 5 a.jonidi@modares.ac.ir ﭼﮑﯿﺪه -1 ﺑﺮرﺳﯽ ﮐﺎراﯾﯽ ﻓﺮاﯾﻨﺪ ﻓﺘﻮﮐﺎﺗﺎﻟﯿﺴﺘﯽ ﻧﺎﻧﻮذرات اﮐﺴﯿﺪ روي در ﺣﺬف آﻻﯾﻨﺪه آﻧﯿﻠﯿﻦ از ﭘﺴﺎب ﺳﻨﺘﺘﯿﮏ
ﻣﻘﺪﻣﻪ ppm ppm VOC MCL USEPA VTOC µ Y.Dong C6H5NH2 J.Antoni o C A.Bozzi Fe/C Fe/C J.Sarasa m
AOP TiO2 ev Resun min ﺷﮑﻞ :1 ﻃﺮح ﺷﻤﺎﺗﯿﮏ راﮐﺘﻮر ﻣﻮرد اﺳﺘﻔﺎده ﺟﻬﺖ ﻓﺮاﯾﻨﺪ ﻓﺘﻮﮐﺎﺗﺎﻟﯿﺴﺘﯽ اﮐﺴﯿﺪ روي اﻟﻒ( راﮐﺘﻮر اﺻﻠﯽ از ﺟﻨﺲ ﭘﻠﮑﺴﯽ ﮔﻠﺲ ب( درﭘﻮش راﮐﺘﻮر ج( ﻏﻼف ﮐﻮارﺗﺰي ﻣﻮرد اﺳﺘﻔﺎده L/ mm Fe2O3 CdS ZrO2 ﻣﻮاد و روشﻫﺎ
ﻣﺸﺨﺼﺎت ﻧﺎﻧﻮذرات اﮐﺴﯿﺪ روي ﻣﻮرد اﺳﺘﻔﺎده در اﯾﻦ ﺗﺤﻘﯿﻖ :1 ﺟﺪول C. Karunakaran mm nm m g/m2 mm Schewan w/m Black light AOP 2 ppm w/m2 Hanger-EC1-UVA ﻣﺸﺨﺼﺎت ﻻﻣﭗ ﮐﻢ ﻓﺸﺎر ﻓﺮاﺑﻨﻔﺶ :2 ﺟﺪول
Elmai S-80 SPSS Excel Batch ﯾﺎﻓﺘﻪ ﻫﺎ Hettich rpm m L/min (Poly tetra fluoro ethylene) PTFE ml µm Mann Falcon Chrompack-CP9001 FID HP-5 m mm ANOVA M
ANOVA ﺷﮑﻞ :3 راﻧﺪﻣﺎن ﺣﺬف آﻧﯿﻠﯿﻦ از ﭘﺴﺎب ﺳﻨﺘﺘﯿﮏ ﺗﻮﺳﻂ ﻓﺮاﯾﻨﺪ ﻓﺘﻮﮐﺎﺗﺎﻟﯿﺴﺘﯽ ﻧﺎﻧﻮذرات اﮐﺴﯿﺪ روي در ﺧﻨﺜﯽ و ﻏﻠﻈﺖﻫﺎي ﻣﺨﺘﻠﻒ ﻧﺎﻧﻮذرات اﮐﺴﯿﺪ روي ﺷﮑﻞ :2 ﺗﺎﺛﯿﺮ ﺟﺪاﮔﺎﻧﻪ ﭘﺮﺗﻮ ﻓﺮاﺑﻨﻔﺶ ﻧﺎﻧﻮذرات اﮐﺴﯿﺪ روي و ﻫﻮادﻫﯽ ﺑﺮ ﺣﺬف آﻧﯿﻠﯿﻦ از ﭘﺴﺎب ﺳﻨﺘﺘﯿﮏ در ﺷﺮاﯾﻂ ﺷﺎﻫﺪ
ANOVA ANOVA Independent ﺷﮑﻞ :5 اﻓﺰاﯾﺶ ﮐﺪورت ﻧﺎﺷﯽ از اﻓﺰودن ﻧﺎﻧﻮذرات اﮐﺴﯿﺪ روي ﺑﻪ ﭘﺴﺎب ﺷﮑﻞ :4 راﻧﺪﻣﺎن ﺣﺬف آﻧﯿﻠﯿﻦ از ﭘﺴﺎب ﺳﻨﺘﺘﯿﮏ ﺗﻮﺳﻂ ﻓﺮاﯾﻨﺪ ﻓﺘﻮﮐﺎﺗﺎﻟﯿﺴﺘﯽ ﻧﺎﻧﻮذرات اﮐﺴﯿﺪ روي در ﻗﻠﯿﺎﯾﯽ و ﻏﻠﻈﺖﻫﺎي ﻣﺨﺘﻠﻒ ﻧﺎﻧﻮذرات اﮐﺴﯿﺪ روي
sample t-test P O2- O2 R+ H2O OH OHo no + hv (UV) ZnO (e- CB + h+ VB) ZnO (h+ VB) + H2O ZnO + H+ + OHo ZnO (h+ VB) + OH- ZnO + OHo ZnO (e- CB) + O2 ZnO + O2-o O2-o + H+ HO2o Organic + OHo Degradation products ZnO ZnO NTU NTU + H ﺑﺤﺚ ZnO(s) + 2H+(aq) Zn2+(aq) + H2O(l) Dong ﺑﺮ راﻧﺪﻣﺎن ﺣﺬف آﻻﯾﻨﺪه آﻧﯿﻠﯿﻦ ﺗﺎﺛﯿﺮ - Magnesia Lu ﺗﺎﺛﯿﺮ ﻏﻠﻈﺖ ﻧﺎﻧﻮذرات اﮐﺴﯿﺪ روي ﺑﺮ ﺗﺠﺰﯾﻪ آﻻﯾﻨﺪه آﻧﯿﻠﯿﻦ
ANOVA P Shifu Cr2O72- COD Ghazi ﻧﺘﯿﺠﻪﮔﯿﺮي m UV-A m m ﺗﺎﺛﯿﺮ زﻣﺎن ﻣﺎﻧﺪ ﺑﺮ راﻧﺪﻣﺎن ﺣﺬف آﻻﯾﻨﺪه آﻧﯿﻠﯿﻦ -
ﻣﻨﺎﺑﻊ 1. Nemerow NL, Agardy FJ, Sullivan P, Salvato JA. Environmental Engineering: Water, Wastewater, Soil and Groundwater Treatment and Remediation. New York: John Wiley & Sons; 2009. 2. Rappoport Z. The Chemistry of Anilines. 1st ed. London: John Wiley & Sons Ltd; 2007. 3. Bell LS, Devlin JF, Gillham RW, Binning PJ. A sequential zero valent iron and aerobic biodegradation treatment system for nitrobenzene. Journal of Contaminant Hydrology 2003;66(3-4):201-17. 4. Brillas E, Casado J. Aniline degradation by electrofenton and peroxi-coagulation processes using a flow reactor for wastewater treatment. Chemosphere. 2002;47(3):241-8. 5. Qi XH, Zhuang YY, Yuan YC, Gu WX. Decomposition of aniline in supercritical water. Journal of Hazardous Materials. 2002;90(1):51-62. 6. Ramanamurthy D, Jones F. Separation of aniline from aqueous solutions using emulsion liquid membranes. Journal of Hazardous Materials. 1999;70(3):157-70. 7. BPIMTO. Proposed Oil, Gas and Petrochemical Industries. Bushehr: Bushehr Province Industry, Mine and Trade Organization (BPIMTO); 2011 [cited 2012 Feb 3]. Available from: http://boushehr.mim.gov.ir/ index.php?module = content&func = viewpage & pageid=6139. 8. OSHA. Occupational safety and health standards. Occupational Safety and Health Administration; 1993. Report No.: 29 CFR-1910. 9. USEPA. OPPT chemical fact sheets, Aniline fact sheet: Support document. United States Environmental Protection Agency; 1994 Dec. Report No.: CAS No. 62-53-3. 10. Dong Y, He K, Yin L, Zhang A. Catalytic degradation of nitrobenzene and aniline in presence of ozone by magnesia from natural mineral. Catalysis Letters. 2007;119(3-4):222-7. 11. Anotai J, Lu MC, Chewpreecha P. Kinetics of aniline degradation by fenton and electro-fenton processes. Water Research. 2006;.40(9):1841-7. 12. Bozzi A, Yuranova T, Lais P, Kiwi J. Degradation of industrial waste waters on Fe/C-fabrics. Optimization of the solution parameters during reactor operation. Water Research. 2005;39(5):1441-50. ﺗﺸﮑﺮ و ﻗﺪرداﻧﯽ...
13. Sarasa J, Cortes S, Ormad P, Gracia R, Ovelleiro JL. Study of the aromatic by-products formed from ozonation of anilines in aqueous solution. Water research. 2002;36(12):3035-44. 14. Crittenden JC, Liu J, Hand DW, Perram DL. Photocatalytic oxidation of chlorinated hydrocarbons in water. Water Research. 1997;31(3):429-38. 15. de Lasa D, Serrano B, Salaices M. Photocatalytic Reaction Engineering. New York: Springer; 2006. 16. Al-Nour GYM. Photocatalytic degradation of organic contaminants in the presence of graphitesupported and unsupported ZnO modified with CdS particles [dissertation]. Nablus: An-Najah National University; 2009. 17. Kansal SK, Singh M, Sud D. Studies on photodegradation of two commersial dyes in aqueous phase using different photocatalysts. Journal of Hazardous Materials. 2007;141(3):581-90. 18. Eslami A, Nasseri S, Yadollahi B, Mesdaghinia A, Vaezi F, Nabizadeh R, et al. Photocatalytic degradation of methyl tert-butyl ether (MTBE) in contaminated water by ZnO nanoparticles. Journal of Chemical Technology & Biotechnology. 2008;83(11):1447-53. 19. Karunakaran C, Senthilvelan S. Fe2O3photocatalysis with sunlight and UV light: Oxidation of aniline. Electrochemistry Communications. 2006;8(1):95-101. 20. Lu MC, Chang YF, Chen IM, Huang YY. Effect of chloride ions on the oxidation of aniline by Fenton s reagent. Journal of Environmental Management. 2005;75(2):177-82. 21. APHA. Standard Methods for the Examination of Waters and Wastewaters. 21st ed. Washington, DC.: American Public Health Association (APHA); 2005. 22. Lizama C, Freer J, Baeza H, Mansilla HD. Optimized photodegradation of reactive blue 19 on TiO2 and ZnO suspensions. Catalysis Today. 2002;76(2-4):235-46. 23. Chen S, Zhao W, Liu W, Zhang S. Preparation, characterization and activity evaluation of p n junction photocatalyst p-zno/n-tio2. Applied Surface Science. 2008;225(5):2478 84. 24. Brillas E, Mur E, Casado J. Iron(II) of the mineralization of aniline using a carbon-ptfe O2fed cathode. Journal of The Electrochemical Society. 1996;143(3):973-82. 25. Brillas E, Mur E, Sauleda R, Sanchez L, Peral J, Domenech X, et al. Aniline mineralization by AOP s: anodic oxidation, photocatalysis, electro-fenton and photoelectron-fenton processes. Applied Catalysis B: Environmental 1998;16(1):31-42.
Iran. J. Health & Environ., 2012, Vol. 5, No. 2 Photocatalytic Removal of Aniline from Synthetic Wastewater using ZnO Nanoparticle under Ultraviolet Irradiation Emad Dehghani fard1, Ahmad Jonidi Jafari2, Roshanak Rezae Kalantari1, Mitra Gholami1, Ali Esrafili1 1 Department of Environmental Health Engineering, School of Public Health, Tehran University of Medical Sciences, Tehran, Iran 2 Department of Environmental Health, Faculty of Medical Sciences, Tarbiat Modares University, Tehran, Iran Received; 15 October 2011 Accepted; 10 January 2012 ABSTRACT Background and Objectives: Aniline has been used in different processes of chemical industries, however due to its side effects on the environment, several methods have been considered for its removal. In this study, we evaluated the performance of photocatalytic process using ZnO nanoparticles (nzno) and ultraviolet (UV) irradiation for removal of Aniline from a synthetic effluent. Materials and Methods: A 5L photocatalytic reactor made from Plexiglas, which the UV lamp (20w) installed in the center of that (inside a quartz jacket), was designed and nzno (0.2-0.5 g/l) was being added into synthetic effluent with Aniline concentration of 250 ppm. After retention times of 30, 60, and 90 min, samples were centrifuged and supernatant was filtered using a 0.2 µ PTFE filter. The liquid-liquid method and Gas Chromatography instrument was used for extraction and analysis respectively. Results: Results showed that the photocatalytic process of nzno+uv could effectively remove Aniline from effluent. Increasing trend in the removal efficiency of Aniline using nzno = 0.5 g/l was slower in comparison with other nzno concentrations and the ANOVA analysis shows no significant difference between removal efficiency of Aniline in different concentrations of nzno. The most removal efficiency of Aniline (76.3%) was observed in alkaline, retention time of 90 min and nzno of 0.5 g/l. Conclusion: It could be concluded that the photocatalytic process of nzno+uv could be suitable technique for Aniline removal from effluents. Keywords: Aniline, ZnO nanoparticles, Ultraviolet radiation, Photocatalytic processes *Corresponding Author: a.jonidi@modares.ac.ir Tel: +98 21 82883563, Fax: +98 21 82883825