Microsoft Word - Natarajan-ed.doc ETASR - Engineering, Technology & Applied Science Research Vol. 3, �o. 2, 2013, 387-390 387 www.etasr.com Rajamohan and Rajasimman: Kinetic Modeling of Dye Effluent Biodegradation by Pseudomonas Stutzeri Kinetic Modeling of Dye Effluent Biodegradation by Pseudomonas Stutzeri Natarajan Rajamohan Dpt of Chemical Engineering, Sohar University, Sohar, Sulatanate of Oman natrajmohan@gmail.com Manivasagan Rajasimman Dpt of Chemical Engineering, Annamalai University, Annamalai Nagar, India simms@rediffmail.com Abstract—Dye industry waste water is difficult to treat because of the presence of dyes with complex aromatic structure. In this research study, the biodegradation studies of dye effluent were performed utilizing Pseudomonas stutzeri in a controlled laboratory environment under anoxic conditions. The effects of operational parameters like initial pH of the effluent and initial Chemical Oxygen Demand (COD) of the effluent on percentage COD removal were studied. A biokinetic model is established giving the dependence of percentage COD removal on biomass concentration and initial COD of the effluent. The biokinetics of the COD removal was found to be first order with respect to both the microbial concentration and initial COD of the effluent. The optimal pH for better bacterial degradation was found to be 8.The specific degradation rate was found to be 0.1417 l/g Dry Cell Mass (DCM) h, at 320 C. Keywords- Dye effluent degradation; biokinetics; anaerobic. I. INTRODUCTION Over 7x10 5 metric tons of synthetic dyes are produced world wide every year for dyeing and printing. A very small amount of dye in water (10-50 mg/l) is highly visible and affects the aesthetic merit, water transparency and gas solubility of water bodies, Dyeing units are found in most countries and their numbers have increased. These industries have shown a significant increase in the use of synthetic complex organic dyes as the coloring material. The annual world production of textiles is about 30 million tones requiring 700,000 tonnes of different dyes which causes considerable environmental pollution problems. Dyes include a broad spectrum of different chemical structures, primarily based on substituted aromatic and heterocyclic groups such as aromatic amine (C6H5-NH2), which is a suspected carcinogen, phenyl (C6H5-CH2) and naphthyl (NO2-OH), the only thing in common is their ability to absorb light in the visible region. The waste water from these industries are characterized by high alkalinity, biological oxygen demand, chemical oxygen demand, total dissolved solids and with dye concentrations usually less than 1 g/dm 3 [1]. Color is the first contaminant to be recognized in wastewater and has to be removed before discharging in to water bodies or on land. The inefficiency in dyeing processes has resulted in 10-15% of unused dyestuff entering the wastewater directly. Color present in dye effluent gives a straightforward indication of water being polluted and discharge of this highly colored effluent can damage directly the receiving water. Furthermore, it is difficult to degrade the mixtures of the wastewater from the textile industry by conventional biological treatment processes, because their ratio of Biochemical Oxygen Demand (BOD)/Chemical Oxygen Demand (COD) is less than 0.3 [2]. The discharges of dye house wastewater into the environment is aesthetically displeasing, impede light penetration, damage the quality of the receiving streams and may be toxic to treatment processes, to food chain organisms and to aquatic life. The degradation of molecules of dyes in the environments by microorganisms is likely to be slow, which means that it is possible for high levels of dye to persist, and potentially accumulate. Due to the low biodegradability of dyes, conventional biological treatment processes are inefficient in treating dye wastewaters. In addition, numerous physical and chemical techniques such as flocculation combined with flotation, electro-flotation, flocculation with Fe(II), Ca(OH)2, membrane filtration, precipitation, ion- exchange, Ozonation and Katox treatment method involving the usage of activated carbon and air mixtures were also used [3]. Even though some of the above mentioned methods are effective, most of them suffer from shortcomings such as excess usage of chemicals, sludge disposal, expensive operating cost, ineffective color reduction for sulfonated azo dyes and poor sensitivity towards shock load conditions. Biological decolonization is employed under either aerobic or anaerobic environment. A number of reports discourage the azo dye decolonization by microorganism under anaerobic conditions as it leads to the formation of corresponding aromatic amines. Even though their reductive cleavage is responsible for colour removal, the formation of aromatic amines is highly undesired as they are reported to be carcinogenic. In the presence of oxygen, aromatic amines can be degraded. Degradation of azo dyes has been studied under aerobic conditions using both pure and mixed microbial cultures. The restrictive environmental legislation, the ecological problem and the high cost of conventional technologies for dye house effluent treatment have resulted in the search of economically viable and technologically suitable wastewater treatment plants. Dye house effluents usually contain azodyes which are highly resistant to biological treatment and these dyes are considered to be recalcitrant xenobiotic compounds because of the presence of N=N bonds ETASR - Engineering, Technology & Applied Science Research Vol. 3, �o. 2, 2013, 387-390 388 www.etasr.com Rajamohan and Rajasimman: Kinetic Modeling of Dye Effluent Biodegradation by Pseudomonas Stutzeri and other possible groups, like the sulphonic group, which are tough to be degraded. It was reported that some anaerobic bacteria could biodegrade dyestuffs by azoreductase activity. However the effluent from biodegradation of dyestuffs could be toxic. Also, reverse coloration may take place when the degradation products are exposed to oxygen. [4]. Because of these above-mentioned problems, full-scale application of bacterial degradation is limited. Also, only few research works have been reported on the aerobic degradation of azo dyes. Therefore, a need exists to develop a novel treatment technology for textile dye effluent treatment to ensure environmental protection from these harmful pollutants. The effectiveness of microbial decolorization depends on the adaptability and the activity of selected microorganisms. Over the past decades, many microorganisms are capable of degrading azo dyes, including bacteria, fungi and yeast [5, 6]. However, the low pH requirement for an optimum activity of the enzymes and the long hydraulic retention time for complete decolorization are the disadvantages of using fungi. In addition, they may inhibit the growth of other useful microorganisms. Thus, large-scale applications of fungal decolorization have been limited. With the aforesaid details in the background, this investigation was aimed to study the feasibility of biodegradation of the dye house effluent by employing the bacterial strain Pseudomonas stutzeri under anoxic conditions. Also, the biokinetic pattern of COD removal of the effluent was studied and the kinetic constants were determined. II. MATERIALS AND METHODS A. Dye house effluent The dye house effluent was collected from a dyeing unit situated in Tirupur region (Tamilnadu, India). The characteristics of the dye house effluent were COD-3200 mg l- 1, BOD-840 mg l-1 and pH 8.2±0.1 [7]. The colour of the effluent was dark red due to the presence of dyes. The effluent was refrigerated at 4ºC and used without any preliminary treatment. B. Microorganism Pure bacterial strain Pseudomonas stutzeri (MTCC NO: 101) was purchased from Microbial type culture collection and gene Bank, Chandigarh, India. The strain was maintained in growth medium whose composition is agar-15g, Beef extract- 1g, Yeast extract-2g, peptone-5g, Sodium chloride-5g in 1 liter of distilled water. The cultures were growth in a controlled environment in a working temperature of 32ºC. C. Estimation of cell mass and COD of effluent with cell free supernatant Samples were withdrawn from the conical flasks and centrifuged at 13,000 rpm for 5 minutes. With the clear supernatant obtained, COD was evaluated [7]. Similar procedures were also followed to evaluate the degradation potential of strains incubated for specified period of time. The initial COD removal data were used to find the microbial activity based on per mg/l of COD removed per gram of Dry Cell Mass (DCM) per unit time. The DCM in suspension was determined after dehydration at 80ºC to constant weight. Control experiment was conducted in parallel with uninoculated flasks. The Pseudomonas stutzeri strain was added in predetermined proportion (0.62 g DCM/l) to the effluent along with the growth medium. In order to find the maximum COD removal percentage of the dye house effluent by the bacterial strains, a test solution containing 0.62 g DCM per liter and the proportionate quantities of growth medium constituents, was incubated under static conditions at 32 ºC. The time courses of percentage COD reduction and effluent COD removal were observed and plotted. In order to find out the concentration of cell mass, a calibration curve was also prepared between the dry weight of cell mass and optical density of the broth at 540 nm. D. Effect of pH Stock culture of the selected bacterium, Pseudomonas stutzeri was prepared by growing a single colony in 100 ml of growth medium in 500 ml conical flasks for 3 days at 32 ºC under static condition. An aliquot of 1 ml of each bacterium was inoculated into a 500 ml conical flask with 10 ml of growth medium plus 100 ml of dye house effluent. As pH is one of the controlling factors of bacterial activity, it is inevitable to study its influence on % COD removal. The pH of the medium was adjusted 4, 6, 8, 10, 12 with 1M HCl. III. RESULTS AND DISCUSSION A. Effect of effluent pH Among the various process variables, pH play a vital role for the optimal activity of bacterial cultures and pH is an influencing factor for nutrient transport across the bacterial cell membrane [8]. To determine the optimal pH for the bacterial activity, a set of batch tests were conducted at different pH. The highest COD removal percentage of 93% was achieved at pH=8. Whereas acidic effluent environment (pH=4, pH=6) reduced the activity of, Pseudomonas stutzeri producing 12% and 58% COD removal respectively. Similar inhibitory effect on % COD removal was achieved when the pH moved towards a more basic region (i.e. pH=10, 12). The influence of pH on the percentage COD removal is illustrated in Figure 1. Fig. 1. Effect of solution pH on degradation of dye house effluent by Pseudomonas stutzeri (t=48 h; Temp=32 o C; M=0.62 g DCM) The microbial action at the actual effluent pH, which was normally in the range of 8.2±0.1, was effective yielding COD removal of 77%. Very similar results have been reported with the decolorization study on acid violet 7 by an isolated Pseudomonas strain [9]. Many researchers have studied the ETASR - Engineering, Technology & Applied Science Research Vol. 3, �o. 2, 2013, 387-390 389 www.etasr.com Rajamohan and Rajasimman: Kinetic Modeling of Dye Effluent Biodegradation by Pseudomonas Stutzeri effect of pH on decolorization of different textile dyes [10, 11, 12, 13].The optimal value for better dye waste water treatment is reported to be often a neutral value or slightly alkaline value [8]. Defale et al.[14] reported the optimal pH range 7.0-8.0 for the removal of remazol Black B by Pseudomonas aeruginosa. Ponraj et al.[15] reported maximum decolorization efficiency (89.0 %) at pH 6.0 for Pseudomonas sp. B. Bio Kinetic Modeling In order to measure the minimum degradation rate of dye house effluent Pseudomonas stutzeri, the static effluent and 0.62 g DCM/l and 10 ml of growth medium was incubated under anoxic condition at 32 o C for 48 hr. Figure 2 shows the time course of COD remaining. Fig. 2. The time course of degradation of dye house effluent by Pseudomonas stutzeri (t=48 h; Temp=32 o C; M=0.62 g dry cell mass) ][ ]][[ ][ ][][ 1 2 1 02 S k k k SEk SK SV dt Sd v m m ++ = + =−= − (1) The below mentioned Equation 2 gives the convenience on analysis of effect of temperature m ndS kM S dt = − (2) where t is the incubation time (h), M is the biomass concentration (mg DCM/l), m is the partial reaction order with respect to biomass, S is the COD value of the effluent (mg/l) and n is its partial reaction order. Here, k is the specific COD removal rate with units (mg (1–n) l (m+n–1) / mgDCM m h). It was reported that (2) could be considered as a modified model of Michaelis Menten rate equation (1), when the parameter Km is not included. The relationship between the COD of the effluent and incubation time depending on the partial reaction order (n) is given by (1 ) (1 ) 0 0 (1 ) 1 , when (n 1) n m n S n kM t S S − − − = − ≠       (3) 0 exp( ), when (n 1) mS kM t S = − ≠       (4) When the plot between incubation time and the COD value was made, a high degree of linearity was observed (R 2 >0.99), as shown in Figure 3. Hence the order of the reaction with respect to effluent COD value was found to be 1.0. Fig. 3. Data fitting and estimation of Bio Kinetic parameters For this set of experiments, used to establish a relationship between biomass concentration and effluent COD removal rate, the incubation time was fixed as 12 h. As shown in Figure 4, a linear relationship (R 2 >0.97) was obtained between biomass concentration M and kM m that indicates m equals to unity. Therefore, the COD removal was a first order reaction with respect to biomass concentration (M). Fig. 4. Effect of cell mass concentration on remaining COD of the effluent at 32 o C The kinetic model of COD removal by the Pseudomonas stutzeri was given by dS kMS dt = − (5) S = S0 exp (− kMt) (6) The value of specific COD removal rate, k, obtained from the slope of the line in Figure 3 was 0.1417 l k gDCMh = at 32°C ETASR - Engineering, Technology & Applied Science Research Vol. 3, �o. 2, 2013, 387-390 390 www.etasr.com Rajamohan and Rajasimman: Kinetic Modeling of Dye Effluent Biodegradation by Pseudomonas Stutzeri IV. CONCLUSION 1. Effective degradation of dye house effluent was achieved by the bacterial strain Pseudomonas stutzeri under anoxic environment. 2. The optimal pH for better degradation of dye effluent was found to be 8.0. 3. The biokinetics of the COD removal was found to be first order with respect to both the microbial concentration and initial COD of the effluent with the rate equation 0.1417 dS MS dt = − 4. 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