Abstract

The photocatalyst TiO2/SiO2 was prepared and used for chlorine dioxide photocatalytic oxidation of simulated fuchsine wastewater under UV irradiation. The removal efficiency of fuchsine treated by photocatalytic oxidation process is higher than that of chemical oxidation process. By using UV-Vis and online FTIR analysis technique, the intermediates during the degradation process were obtained. The benzene ring in fuchsine was degraded into quinone and carboxylic acid and finally changed into carbon dioxide and water during the photocatalytic oxidation. The degradation reaction mechanism of fuchsine by UV irradiation chlorine dioxide photocatalytic oxidation was proposed based upon the experiment evidence.

1. Introduction

The effluents produced by some of our industries are harmful to the health and general well-being of man. When undesirable substances are present in liquid effluents, it can be disastrous as their presence pose severe threat to the immediate recipients. Wastewaters from various industries, factories, laboratories, and so forth are serious problems to the environment. Addressing these problems calls out for a tremendous amount of research to be conducted to identify robust new methods of purifying water at lower cost and with less energy, while at the same time minimizing the use of chemicals and impact on the environment [1].

In recent years, a variety of wastewater treatment techniques have been applied to degrade and remove refractory materials from wastewaters, including chemical oxidation [2], biodegradation [3], electrochemical oxidation degradation [4], catalytic oxidation degradation [5, 6], and so on. Also, to obtain a high removal efficiency of hazardous materials, a combination of physical and chemical techniques should also be employed [7]. These wastewater treatment processes generate very toxic wastewater, whose treatment is often difficult due to the presence of some non-biodegradable species with complex structure. Hence there is considerable current interest in developing alternative and more cost-effective methods to treat those refractory materials.

Advanced oxidation processes (AOPs) have been developed to meet the increasing need of an effective wastewater treatment. AOP generates powerful oxidizing-agent hydroxyl radicals which completely destroy major classes of organic pollutants at ambient conditions. The combination of UV irradiation with photocatalysts is one of such methods which have attracted considerable attention in recent years, due to its effectiveness in mineralization (i.e., conversion to inorganic species) of organic materials [8, 9]. Heterogeneous photocatalysis through illumination of UV on a semiconductor surface such as TiO2 is an attractive advanced oxidation process [10]. Such a UV-TiO2-based photocatalytic oxidation system exhibits some attractive characteristics. First, TiO2 is stable, insoluble, nontoxic, and environmentally acceptable by being fairly inert biologically and chemically. Second, TiO2 is inexpensive reusable. Third, the photocatalyst titanium dioxide (TiO2) is a wide band-gap semiconductor (3.2 eV), has high photoactivity, and is successfully used as a photocatalyst for the treatment of organic [11, 12] and dye pollutants [1315].

The mechanism constituting heterogeneous photocatalytic oxidation processes has been discussed extensively in the literature [16, 17]. Briefly, when a semiconductor such as TiO2 absorbs a photon of energy equal to or greater than its band gap width, an electron may be promoted from the valence band to the conduction band (ecb) leaving behind an electron vacancy or “hole” in the valence band (hvb+). If charge separation is maintained, the electron and hole may migrate to the catalyst surface where they participate in redox reactions with absorbed species. Specially, hvb+ may react with surface-bound H2O or OH to produce the hydroxyl radical, and ecb is picked up by oxygen to generate superoxide radical anion (O2).

One practical problem in using TiO2 as a photocatalyst is the undesired electron-hole recombination, which, in the absence of proper electron acceptor or donor, is extremely efficient and represents the major energy-wasting step thus limiting the achievable quantum yield. One strategy to inhibit electron-hole pair recombination is to add other (irreversible) electron acceptors to the reaction. They could have several different effects, such as (1) to increase the number of trapped electrons and, consequently, avoid recombination, (2) to generate more radicals and other oxidizing species, (3) to increase the oxidation rate of intermediate compounds, and (4) to avoid problems caused by low oxygen concentration. In highly toxic wastewater where the degradation of organic pollutants is the major concern, the addition of electron acceptors to enhance the degradation rate may often be justified. Hydrogen peroxide used as electron acceptors was investigated in solar-light-induced and TiO2-assisted degradation of textile dye reactive blue 4 [18]. The enhanced photodegradation efficiency in the presence of hydrogen peroxide may be either directly via conduction band electrons or indirectly via superoxide radical anion which produces hydroxyl radicals. The results indicate that the mineralization of the fragments is tremendously faster in the presence of hydrogen peroxide.

Taking the above-mentioned concept into account, the present study focused on the chlorine dioxide photocatalytic degradation of wastewater containing fuchsine by UV irradiation in the presence of titanium dioxide, where the strong oxidizer chlorine dioxide was also used as the electron acceptor. In our experiment, the photocatalyst TiO2/SiO2 was prepared. Moreover, in order to investigate the inherent essence of photocatalytic degradation mechanism, UV-Vis, FTIR, and online FTIR spectroscopy were also introduced. The intermediates were detected by online FTIR spectroscopy during the chlorine dioxide photocatalytic oxidation process. The degradation reaction mechanism of fuchsine by chlorine dioxide photocatalytic oxidation was proposed on the basis of the experiment evidences.

2. Experimental

2.1. Materials

The reagents used in the experiment were of analytical grade. The pure ClO2 aqueous solution was prepared by mixing a sulphuric acid aqueous solution and a sodium chlorite aqueous solution, where the sulphuric acid aqueous solution was added dropwise to the sodium chlorite aqueous solution. Subsequently, the gas obtained was absorbed by a sodium chlorite aqueous solution to remove the impurities, for example, chlorine. The remaining gas, chlorine dioxide, was absorbed by distilled water. Also, the ClO2 aqueous solution was stored in darkness. The ClO2 concentration was determined by the iodometric titration method before use. The concentration of fuchsine was 150 mg/L.

The photocatalyst of TiO2/SiO2 was prepared according to the method of impregnation [19], immersing certain amounts of silica gel pretreated in Muffle furnace 4 h at 500°C into the mixture of butyl titanate and cyclohexane (V(Ti(OBu)4)/V(C6H12))=4) for 15 h, then evaporated cyclohexane at 40°C water bath and dried the catalyst at 120°C for 6 h. Subsequently, the catalyst was calcined in Muffle furnace by three-step at air atmosphere: 200°C for 1 h, 350°C for 1 h, 450°C for 8 h. The formatted active component TiO2 was loaded on the surface of silica gel, and the photocatalyst of TiO2/SiO2 was obtained.

2.2. Method

100 mL of simulated wastewater containing fuchsine was added in a 250 mL three-necked flask, where the temperature was measured by thermometer. The pH value was adjusted by hydrochloric acid solution and sodium hydroxide to a certain value. The sample containing the appropriate concentration of ClO2 and photocatalyst was irradiated by means of UV lamps under magnetic stirring. Throughout the degradation experiment, the sample to be analyzed was withdrawn regularly from the flask and filtered to remove the photocatalyst. Then, the absorbance of the sample at 543 nm was obtained by UV-Vis spectrophotometer, and the removal efficiency was obtained according to the Lambert-Beer standard curve.

The removal efficiency (𝐸) of fuchsine was calculated as follows:𝐶𝐸=0𝐶𝑖𝐶0×100%,(1) where 𝐶0 is the initial concentration of wastewater containing fuchsine, 𝐶𝑖 is the concentration of sample treated under a certain condition.

2.3. UV-Vis Spectrophotometric Analysis

The simulated wastewater containing fuchsine, the effluent of chemical oxidation, and the effluent of photocatalytic oxidation were diluted 40 times before the analysis on TU-1800 PC UV-Vis spectrophotometer (Beijing Puxi Tongyong Instrument Company, Beijing, China). The UV-Vis spectrum of the water sample could be obtained in the range of 200 nm to 1000 nm.

2.4. FTIR Analysis

FTIR spectra were recorded from 400 to 4000 cm−1 wavenumber range with averaging 32 scans at a resolution of 4 cm−1 on a Bruker Tensor-27 FTIR spectrophotometer. Both the effluent of chemical oxidation and the effluent of photocatalytic oxidation were evaporated in a water bath at 80°C. Therefore, the solid samples were obtained and were used for the analysis of FTIR.

2.5. Online FTIR Analysis during the Wastewater Treatment

The online FTIR analysis was performed on a ReactIR 4000 spectrophotometer (Mettler-Toledo AutoChem, Inc., USA). FTIR spectra were recorded from 400 to 4000 cm−1 wavenumber range at a resolution of 8 cm−1. 50 mL simulated wastewater containing fuchsine was added into a 250 mL flask, where the pH value was adjusted to 5.0 by hydrochloric acid solution. Then, chlorine dioxide solution, by maintaining the concentration of chlorine dioxide 6.14 mg/L, and 0.5 grams of TiO2/SiO2 photocatalyst were added. In addition, using a magnetic stirrer allows for effective mixing in flask during the online FTIR measurement.

3. Results and Discussion

3.1. Lambert-Beer Standard Curve

The Lambert-Beer law is the linear relationship between absorbance and concentration of an absorber. The general Beer-Lambert law is usually written as𝐴=K𝑏𝑐,(2) where 𝐴 is the measured absorbance, K is a wavelength-dependent absorption coefficient, 𝑏 is the path length, and 𝑐 is the sample concentration.

When the path length 𝑏 is a constant, 𝐴 is proportional to 𝑐. However, this theory is confirmed only in the limited range of the initial concentrations of fuchsine. Therefore the UV-Vis spectra of a series of dilutions from the solution of fuchsine were recorded at 543 nm. Good linear fits between 𝐴 and 𝑐 according to Lambert-Beer law have been observed for fuchsine concentrations between 10 and 30 mg/L. The linear equation is as follows:𝐴=0.0378+0.02204𝑐,(3) where the linear correlation coefficient is 0.994.

3.2. The Wastewater Treatment Process

The treatment conditions were as follows: the volume of wastewater containing 150 mg/L fuchsine was 50 mL, ClO2 concentration was 6.14 mg/L, pH value was 5.0, the distance between UV lamp and flask was 20 cm, UV irradiation time was 13 min, and photocatalyst dosage was 0.5 grams. For chemical oxidation, the dosage of photocatalyst was zero. The removal efficiency of fuchsine by UV irradiation chlorine dioxide photocatalytic oxidation could reach 79.88%, comparing with 46.01% of chlorine dioxide chemical oxidation.

The photocatalytic oxidation process was superior to the chemical oxidation process. The enhancement effect of the photocatalytic oxidation arises mainly from two aspects. The process is initiated upon UV irradiation of the semiconductor with the formation of high-energy electron/hole pairs, and the reaction of the holes with water molecules and hydroxyl ions adsorbed on the surface of TiO2 yields hydroxyl radicals. On the other hand, the resulting hydroxyl radicals, being very strong oxidizing agents, can oxidize the materials of fuchsine into water and carbon dioxide. The strong oxidizer, chlorine dioxide, also acts as an electron acceptor to accept the electron preventing the electron and hole combined together. Therefore, the removal efficiency of fuchsine treated by photocatalytic oxidation process is higher than that of chemical oxidation process.

3.3. Spectrophotometric Analysis and Characterization
3.3.1. UV-Vis Spectrophotometric Analysis of Pollutant Changes

In order to study the pollutant changes during the oxidation process, it is necessary to investigate the UV-Vis spectra before and after chlorine dioxide oxidation treatment. Figure 1 represents the UV-Vis spectra of water samples before and after oxidation.

As shown in Figure 1, the simulated wastewater containing fuchsine has a strong absorption peak at 530 nm (see curve 1), which belongs to the characteristic absorption peak of the longer conjugated pi bonding system of fuchsine molecule. The absorption peak at 530 nm disappeared after chemical oxidation or photocatalytic oxidation (see curve 2 and 3). It indicates that the longer conjugated pi bonding system of fuchsine molecule can be easily oxidized by chlorine dioxide.

The simulated wastewater containing fuchsine has a strong absorption peak at 285 nm (see curve 1), which belongs to the characteristic absorption peak of benzene ring. The absorption intensity at 285 nm decreased after chemical oxidation (see curve 2). We could find that the absorption intensity at 285 nm further decreased after photocatalytic oxidation (see curve 3). This evidence indicated that the simulated wastewater treated by chemical oxidation or photocatalytic oxidation still contained some benzene ring compounds. The chlorine dioxide chemical oxidation or photocatalytic oxidation has the degradative ability to benzene ring compounds to some extent.

By comparing the peak intensity in the UV-Vis spectra of chemical oxidation and photocatalytic oxidation, it indicates that the extent of removal efficiency by photocatalytic oxidation is greater than that of chemical oxidation.

3.3.2. FTIR Analysis of Pollutant Changes

In order to study the pollutant changes during the oxidation process, the FTIR spectra before and after chlorine dioxide oxidation treatment were further investigated. Figure 2 represents the FTIR spectra of fuchsine samples before and after oxidation.

In the FTIR spectrum of fuchsine (curve 1 in Figure 2), the absorptions near 3317 cm−1 and 3175 cm−1 are assigned to N–H stretching vibration of primary amine and =NH2+Cl. The absorption near 1633 cm−1 is assigned to C=C stretching vibration. The absorptions near 1585 cm−1 and 1460 cm−1 are assigned to benzene ring stretching in aromatic compounds. The absorptions near 1168 cm−1 and 1063 cm−1 are assigned to the C–N stretching vibration of aniline in fuchsine.

In the FTIR spectrum of chemical oxidation (Curve 2 in Figure 2), the absorption near 3421 cm−1 is assigned to O–H stretching vibration in carboxylic acids. The absorption near 3145 cm−1 is assigned to N–H stretching vibration of primary amine. The absorption near 1523 cm−1 is assigned to benzene ring stretching in aromatic compounds, which indicates that the benzene ring has not been totally oxidized by chlorine dioxide. There is no C=O stretching absorption peak in the FTIR spectrum of fuchsine. However, there is a new strong absorption near 1726 cm−1, which is assigned to the C=O stretching in carboxylic acids, after treated by chemical oxidation. Also, there is a new absorption near 1631 cm−1, which is assigned to the C=O stretching in quinone or conjugated carboxylic acids, after treated by chemical oxidation. That is to say, the benzene ring in fuchsine was degraded into carboxylic acids, quinone, or conjugated carboxylic acids. At the same time, a new absorption near 1406 cm−1, which is assigned to nitrate, appeared. It indicated that the primary amine was oxidized to nitrate by chlorine dioxide.

In the FTIR spectrum of photocatalytic oxidation (Curve 3 in Figure 2), the absorption near 3421 cm−1 is assigned to O–H stretching vibration in carboxylic acids. The absorption near 3145 cm−1 is assigned to N–H stretching vibration of primary amine. The absorption near 1507 cm−1 is assigned to benzene ring stretching in aromatic compounds, which indicates that the benzene ring has not been totally oxidized by chlorine dioxide. There is no C=O stretching absorption peak in the FTIR spectrum of fuchsine. However, there is a new strong absorption near 1683 cm−1, which is assigned to the C=O stretching in quinone or conjugated carboxylic acids, after treated by photocatalytic oxidation. That is to say, the benzene ring in fuchsine was degraded into quinone or conjugated carboxylic acids. At the same time, a new absorption near 1403 cm−1, which is assigned to nitrate, appeared. It indicated that the primary amine was oxidized to nitrate by chlorine dioxide.

3.3.3. Online FTIR Analysis of Degradation Mechanism

In order to investigate the mechanism of the chlorine dioxide photocatalytic oxidation, the online FTIR was applied to detect and analyze the products formed during oxidation process. Figure 3 presents the 3D online infrared spectrum of wastewater treatment by chlorine dioxide photocatalytic oxidation process. The 3D means absorbance, wavenumber, and reaction time. In Figure 3, the strong absorptions near 3315 cm−1 and 1636 cm−1 are assigned to the O–H stretching of water and the H–O–H bending of water, respectively.

Two intermediates were detected automatically during the online FTIR analysis. Its FTIR spectra were obtained. In the FTIR spectrum of intermediate 1 (Figure 4), the absorption near 1107 cm−1 is assigned to the O–H in-plane deformation in carboxylic acids. The absorption near 1748 cm−1 is assigned to the C=O stretching in carboxylic acids, which should be the product of ethanedioic acid in the degradation reaction mechanism. The absorption near 1652 cm−1 is assigned to the C=O stretching in p-quinone or carboxylic acids, which is conjugated with C=C double bond. It should be the product of p-quinone or butenedioic acid in the degradation reaction mechanism. The absorptions near 1546 cm−1, 1519 cm−1, and 1509 cm−1 are assigned to the C=C stretching in ethylene, which is conjugated with C=O bond. It should be the product of p-quinone or butenedioic acid in the degradation reaction mechanism. Therefore, intermediate 1 should be one of the p-quinone, butenedioic acid, or ethanedioic acid.

In the FTIR spectrum of intermediate 2 (the figure is omitted), the absorption near 1605 cm−1 is assigned to the C=O stretching in p-quinone or carboxylic acids, which is conjugated with C=C double bond. It should be the product of p-quinone or butenedioic acid in the degradation reaction mechanism. Therefore, intermediate 2 should be one of the p-quinone or butenedioic acid.

Figure 5 gives the intermediate 1 relative concentration (c) versus reaction time. Figure 6 gives the intermediate 2 relative concentration versus reaction time. As shown in Figures 5-6, the relative concentrations of intermediates 1 and 2 increase with reaction time. Therefore, intermediate 1 should be one of the p-quinone, butenedioic acid, or ethanedioic acid. Intermediate 2 should be one of the p-quinone or butenedioic acid.

3.4. The Mechanism of Chlorine Dioxide Photocatalytic Oxidation of Fuchsine

Fuchsine was oxidized by chlorine dioxide and hydroxyl radical into p-quinone and carboxylic acids during the photocatalytic oxidation process. Finally, it was changed into carbon dioxide and water. Therefore, the degradation reaction mechanism of fuchsine by chlorine dioxide and hydroxyl radical oxidation was proposed based upon the experiment evidence. The mechanism was presented in Figure 7.

4. Conclusions

(1)The chlorine dioxide photocatalytic oxidation process is an interesting technique for the treatment of wastewater. The removal efficiency of fuchsine treated by photocatalytic oxidation process is higher than that of chemical oxidation process. It may have great practical significance for the design of actual wastewater treatment process.(2)The research on the degradation mechanism showed that the UV irradiation could induce the titanium dioxide to generate an electron-hole (e/h+), where the h+ oxidizes strongly OH and H2O to produce hydroxyl radical (HO), and the e combines with O2 to form superoxide ion (O2). The stronger oxidant of HO and O2 oxidizes fuchsine to produce quinone and carboxylic acids during the oxidation process. In the end, it was degraded into water and carbon dioxide. Moreover, the strong oxidizer chlorine dioxide was not only used to oxidize fuchsine, but also used as the electron acceptor, which could inhibit electron-hole pair recombination to enhance the degradation rate. The result may have great importance for the theoretical study of wastewater treatment.(3)By using UV-Vis and online FTIR analysis technique, the intermediates during the degradation process were obtained. It was useful to investigate the degradation reaction mechanism of the pollutants. The result may have important theoretical significance.

Acknowledgments

The authors would like to thank the financial support from the Shandong Provincial Natural Science Foundation (no. ZR2009BM007) and the Scientific Research Foundation for the Returned Overseas Chinese Scholars, State Education Ministry, China.