This paper presents some of the experimental results from a study conducted to demonstrate the potential use of photocatalytic oxidation for decolorization and COD reduction of wastewater from 5–fluorouracil manufacturing. A series of batch experiments, were carried out using diluted solutions of the wastewater with 0.1 percent w/v TiO2. Low pressure mercury lamps were used to simulate the UV part of sunlight. The experiments showed that a complete decolorization and a substantial reduction of COD was achieved within 20 hours with a 20 percent solution. During the reaction period, the pH was noted to decrease considerably, indicating formation of acids. Adding hydrogen peroxide to the solution was found to significantly increase the reaction rates. Adding 2400 ppm of H2O2 gave an 80 percent decrease in color in one hour and a 70-80 percent decrease in COD in 20 hours. The influence of UV-light intensity was also examined. This experiment showed that with a UV-intensity of 15 W/m2, i.e., a cloudy day, the decolorization rate was still considerable, while the COD reduction rate was very low.

Issue Section:
Research Papers
Topics:
Manufacturing, Wastewater treatment, Ultraviolet radiation, Sewage, Chemical kinetics, Hydrogen, Mercury lamps, Oxidation, Pressure, Sunlight, Water
1.
Bedford, J. R., second reference from Techno Economics.
2.
Blake
D. M.
,
Webb
J.
,
Turchi
C.
, and
Magrini
K.
,
1991
Kinetic and Mechanistic Overview of TiO2-photocatalysed Oxidation Reactions in Aqueous Solutions
,”
Solar Energy Materials
, Vol.
24
, pp.
584
593
.
3.
Carey
J. H.
,
Lawrence
J.
, and
Tosine
H. M.
,
1976
Photodechlorination in Aqueous Suspensions
,”
Bulletin of Environmental Contamination and Toxicology
, Vol.
16
, pp.
697
701
.
4.
Carlin
V.
,
Ninero
C.
, and
Pelizzetti
E.
,
1990
Effect of Chlorine on Photocatalytic Degradation of Organic Contaminants
,”
Environmental Technology
, Vol.
11
, pp.
919
926
.
5.
Gibbs, C. R., 1993 “Introduction to Chemical Oxygen Demand,” Technical Information Series Booklet No. 8, Hach Company, Loveland, CO.
6.
Goswami, D. Y., Klausner, J., Mathur, G. D., Martin, A., Schanze, K., Wyness, P., Turchi, C, and Marchand E., 1993, “Solar Photocatalytic Treatment of Groundwater at Tyndall AFB, Field Test Results,” Solar 93, Proceedings of American Solar Energy Society Annual Conference, Apr. pp. 235-239.
7.
Hach Water Analysis Handbook, 1992 2nd ed., Hach Company, Loveland, CO. 1992
8.
Katritzky, A. R., and Rees, C. W., 1984 Comprehensive Heterocyclic Chemistry The Structure, Reaction, Synthesis and Use of Heterocyclic Compounds, Vol. 3, Part 2B, Pergamon Press.
9.
Matthews
R. W.
,
1990
Purification of Water with Near-UV Illuminated Suspensions of Titanium Dioxide
,”
Water Resources
, Vol.
24
, No.
5
, pp.
653
660
.
10.
Matthews
R. W.
,
1991
Photooxidative Degradation of Colored Organics in Water Using Supported Catalyst TiO2 on Sand
,”
Water Resources
, Vol.
25
, No.
10
, pp
1169
1176
.
11.
Minero
C
,
Aliberti
C.
,
Pelizzetti
E.
,
Terzian
R.
, and
Serpone
N.
,
1991
Kinetic Studies in Heterogeneous Photocatalysis 6AM1 Simulated Sunlight Photodegradation Over Titania in Aqueous Media: A First Case of Fluorinated Aromatics and Identification of Intermediates
,”
Langmuir
, Vol.
7
, No.
5
, pp
928
936
.
12.
O¨berg, V., Goswami, D. Y., and Svedberg, G., “Photocatalytic Detoxification of Water Containing Volatile Organic Compounds,” Solar Engineering 1994, Proceedings of the ASME International Solar Engineering Conference, pp. 147–153.
13.
Ollis
D. F.
,
Pelizzetti
E.
, and
Serpone
N.
,
1991
, “
Destruction of Water Contaminants
,”
Environ Sci Technol.
, Vol.
25
, No.
9
, pp
1523
1529
.
14.
Ollman, J., personal communication, 1993 PCR Chemicals, Gainesville, FL.
15.
Pacheco, J. E., and Holmes, J. T., 1990, “Falling-Film and Glass Tube Solar Photocatalytic Reactors for Treating Contaminated Water,” Emerging Technologies in Hazardous Waste Management, ACS Symposium Series, Washington D.C.
16.
Peterson
M. W.
,
Turner
J. A.
, and
Nozik
A. J.
,
1991
Mechanistic studies of Photocatalytic Behavior of TiO2 Particles in a Photoelectrochemical Slurry Cell and Relevance to Photodetoxification Reactions
,”
The Journal of Physical Chemistry
Vol.
95
, No.
1
, pp
221
225
.
17.
Tseng
J. M.
, and
Huang
C. P.
,
1991
Removal of Chlorophenols from Water by Photocatalytic Oxidation
,”
Water Science Technology
, Vol.
23
, pp.
377n–387
377n–387
.
18.
Turchi
C. S.
, and
Ollis
D. F.
,
1989
Mixed Reactant Photolysis: Intermediates and Mutual Rate Inhibition
,”
Journal of Catalysis
, Vol.
119
, pp.
483
496
.
19.
Zaidi, AH., Goswami, D. Y., and Wilkie, A. C, 1995 “Solar Photocatalytic Post-Treatment of Anaerobically Digested Distillery Effluent,” Proceedings of the 1995 Annual Conference of the American Solar Energy Society, pp. 51–56.
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