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International Journal of Environment Science and Technology
Center for Environment and Energy Research and Studies (CEERS)
ISSN: 1735-1472 EISSN: 1735-2630
Vol. 1, Num. 4, 2004, pp. 265-271

International Journal of Enviornmental Science and Technology, Vol. 1, No. 4, Winter 2004, pp.265-271

Biosorption of Pb, Cd, Cu and Zn from the wastewater by treated Azolla filiculoides with H2O2/MgCl2

1M. Taghi ganji, *1M. Khosravi and 2R. Rakhshaee

1Department of Applied Chemistry, Islamic Azad University, North Tehran Branch, Tehran, Iran 2Department of Applied Chemistry, Islamic Azad University, Rasht Branch, Rasht, Iran

*Corresponding Author, E-mail: drm_khosravi@yahoo.com

Code Number: st04032

Abstract

The adsorption of heavy metals onto treated Azolla filiculoides by H2O2/MgCl2, as a cosmopolitan free-floating waterfern, was investigated from aqueous solutions in the batch biosorption experiments. The maximum uptake capacities of the collected Azolla from rice field at the optimal conditions for Pb, Cd, Cu and Zn ions were approximately 228, 86, 62 and 48 mg/g (dry Azolla), respectively. On the other hand, the maximum uptake capacities of the collected Azolla from the Anzali International Wetland in the north part of Iran at the same conditions for these heavy metals were about 124, 58, 33 and 34 mg/g (dry Azolla), respectively. Such decrease of uptakes is due to the pollution of Anzali International Wetland, which reduces the capacity uptake of metals. The recovery of biosorbed heavy metals from the rice field Azolla was carried out by HCl and NaCl desorbents that the recovery of 64- 86% and 51-72% was occurred, respectively.

Key words: Azolla filiculoides , batch biosorption, heavy metals

Introduction

The different methods are used for the removal of heavy metals as important contaminants in water and wastewater. In the chemical methods, to effectively decrease of heavy metals to acceptable levels require a large excess of chemicals, which increase the costs because of generating the voluminous sludge (Spearot and Peck, 1984). On the other hand, a number of methods exist for the removal of heavy metals from liquid waste when they are present in high concentrations. These include methods such as precipitation, evaporation, electroplating, ion exchange and membrane processes (Matheickal and Yu, 1999). In the meantime, biosorption of heavy metals from aqueous solutions is a relatively new technology for the treatment of industrial wastewater. The major advantages of biosorption technology are their effectiveness in reducing the concentration of heavy metal ions to very low levels and the use of inexpensive biosorbent materials (Volesky, 1990 and 1994). Furthermore, biosorption methods often provide better results than activated carbon and natural zeolites and are comparable to synthetic ion exchange resins (Matheickal and Yu, 1997).

An adsorbent material (biosorbent), both living and nonliving, is derived from suitable biomass can be used for the effective removal and recovery of heavy metal ions from wastewater streams (Niu, et al., 1993 and Muraleedharan, et al., 1995). These include bacteria (Ozdemir, et al., 2003), fungi (Fourest, et al., 1994), yeast (Volesky, et al., 1993), marine algae (Kaewsarn, 2002) and others.

Biosorption in natural or uncontrolled situations typically involves a combination of active and passive transport mechanisms starting with the diffusion of the metal ion to the surface of the microbial cell (Donmez, et al., 1999). The batch biosorption of the metals on biomass were best described by Langmuir isotherms (Feng and Aldrich, 2003).

Azolla is a small aquatic fern. In fact, it is a symbiotic pair of Azolla filiculoides and a heterocystous blue-green alga Anabaena azollae. It has been used as a fertilizer in botanical gardens because of nitrogen-fixing capability (Peters and Meeks, 1989). Azolla has been used for several decades as green manure in rice fields. On the other hand, it has negative effects on the aquatic ecology due to its capable of colonizing rapidly to form dense mats over water surfaces. Controlling its reproduction has been deemed necessary in some Azolla-abundant areas like South Africa (Ashton and Walmsley, 1976) and the north part of Iran. In this regard, the development of an Azolla-based biosorbent for wastewater treatment, especially in developing countries, may benefit environmental problems, by removing heavy metals from water using this weed (Zhao, et al., 1999). Azolla has been shown to be able to effectively adsorb hexavalent and trivalent chromium, zinc (II) and nickel (II) from solutions and electroplating effluent (Zhao, et al., 1997, 1998 and 1999) and gold (III) from aqueous solution (Antunes, et al., 2001).

The initial binding and exchange of heavy metal ions to insoluble constituents in the Azolla matrix most probably involves cell wall charged groups (such as carboxyl and phosphate). Pectin and Cellulose are important polysaccharides constituent of plant cell walls, made of fragments of polygalacturonic acid chains, which interact with Ca2+ and Mg2+ (as the important exchanged ions with heavy metals) to form a three dimensional polymer by (–COO)2Ca and or (–COO)2Mg bindings as the ion exchanging bases (Jauneau, et al., 1997; Kamnev, et al., 1998 and Iijima, et al., 2002). K+ and Na+ are mostly present in Azolla cell as soluble salts (Cohen-Shoel, et al., 2002 a). In this study, biomass oxidation in the presence of MgCl2 in the activating process of the nonliving Azolla filiculoides for batch biosorption of Pb2+, Cd2+, Cu2+ and Zn2+ (separately) were considered. The effects of HCl and NaCl as recovery agents also were investigated.

Materials and Methods

Preparing and treating of Azolla

Fresh Azolla (as raw living biomass) was collected from the surface of rice fields and Anzali Wetland in the south shores of Caspian Sea, Gilan province, the north part of Iran. 2 g. of Azolla was washed three times with deionised water (each time 100 ml. for 30 min.) and was air-dried in sunlight. Azolla (as raw non-living biomass) then was sieved to particles of 1.5-2.0 mm. before use. Azolla was treated as follows: the Azolla samples (each sample 2 g.) were soaked in 2 M. MgCl2 at presence of 30 ml. H2O2 8 mM., as the optimal values for 12 h. under 125 rpm. and away from the light at pH 7. The samples were washed with deionised water. Because Azolla by alkali washing at pH 10-11 loses the minor quantities of its exchanger cations such as Mg2+ (Cohen, et al., 2002 b), our samples were soaked in NaOH solution at pH 10.5 (as activation pH) for 6 h. The treated Azolla samples were washed three times with deionised water (each time 100 ml. for 0.5 min.) to removal excess Mg ions (unadsorbed) from the Azolla. These activated Azolla samples were then dried in oven at 60 ºC for 8 h. The pH of Samples was adjusted by using 0.1 M. NaOH and 0.1 M. HCl.

Experimental work

The Pb2+, Cd2+, Cu2+ and Zn2+ stock solutions were prepared by dissolving their corresponding analytical grade salts of Pb(NO3)2, CdCl2·2.5H2O, CuCl2·5H2O and ZnSO4 (Merck) in distilled water. The ion concentrations in stock solutions were about 4 g/l. For obtaining of adsorption isotherms, a series of flasks (250 ml., as batch biosorption experiments) were prepared containing heavy metal solutions (100 ml.) of known concentrations (Co) varying from 0.38 to 4.6 mM. by diluting of stock solutions with distilled water. For the study of batch biosorption, separately and/or comparative study, each solution contained one metal ion. The mounts of activated Azolla (200 mg.) were added to the flasks (biomass dose 2 g/l) and the mixtures agitated on a rotary shaker for 10 h. The pH of sample solutions were adjusted by using 0.1 M. HCl or 0.1 M. NaOH during the equilibrium period, at the obtained optimal values for each heavy metal viz. pHs 5.5, 6, 5.5 and 6.7 for removal of Pb2+, Cd2+, Cu2+ and Zn2+, respectively. The experiments were performed at room temperature (22 ± 2°C). In the temperature range of 10-50°C there are no, or very minor changes to the surface and chemistry of the groups involved in sequestering the metal ions from solution (Sanyahumbi, et al., 1998). The biomass was removed by filtration through a 0.45 µm. membrane filter (Millipore) and the filtrate was measured for ion content (Ce) by a Shimadzu Model AA-680 Flame Atomic Absorption Spectrophotometer (Japan).

Results

The optimization of the biosorption pH and the used H2O2/MgCl2 (as biomass treatment agents) were performed for the rice field Azolla filiculoides and these results were then used both for the fixing of adsorption isotherms by the wetland and the rice field Azolla filiculoides .

Effect of pH on biosorption processes

Figure 1 shows the biosorption of Pb2+, Cd2+, Cu2+ and Zn2+ (Co was 1mM for each metal ions) were increased up to pH 5.5, 6, 5.5 and 6.7, respectively. The decreasing of biosorption levels by lowering pH can be explained due to competition between protons and metal ions for the capturing same sites, which at low pHs, metal ions do not successful. Also it may be explained dues to the dissociation of formed three-dimensional structure from pectin to the monomers by hydrolysis of polysaccharides at the acidic pHs. In the recent case, the trace quantities of biosorbed heavy metals in all probability are desorbed from the monomers, easily.

Effect of H2O2 and MgCl2 on Azolla treatment

As can be seen from Figure 2a,and b the use of MgCl2 in the activation (treatment) process even in absence of H2O2 increases the removal of heavy metals in the biosorption process. Co was 1 mM. for each metal ions and biosorption pH was kept at the obtained optimal values from Figure 1. The used H2O2 volume was 30 ml. The increasing heavy increased, proportionately. The highest metals removal was obtained in consequence of using 2 M. MgCl2 and 30 ml. H2O2 8 mM. by the treated Azolla at the optimal biosorption pHs for each heavy metal ion (Figure 2a,and b). It may be explained as follows: the cell wall polysaccharides such as cellulose and pectin can be oxidized using H2O2 as oxidant agent (Shao, et al., 2003; Pacoda and Montefusco, 2004 and Robert and Barbati, 2002). Therefore in the treatment process, H2O2 can be converts the more hydroxyl groups of cell wall polysaccharides of Azolla such as cellulose and pectin to free carboxyl groups. This state increases (–COO)2Mg bindings, as the ion exchanging bases metals biosorption in consequence of the rising MgCl2 concentration can be due to Mg2+ replacement as an ion exchanger, instead of the Azolla removed ions. Because, it had been showed the lose of various quantities of exchanger ions viz. Ca2+, Mg2+, K+ and Na+ from the raw nonliving Azolla in consequence of washing by the solutions with neutral pH (Cohen, et al., 2002 a). Therefore Azolla loses the quantities of exchanger ions, as the result of washing by deionised water (pH 7) in the preliminary stage, prior to experimental work in the present study. On the other hand, the increasing of used H2O2 in the treatment process in absence of MgCl2 has not remarkable effect on the removal of heavy metals in the biosorption process. But the using H2O2 increases heavy metal biosorption, remarkably in cases when Mg ions as the exchanger ions are at presence of MgCl2 in the treated Azolla cell biomass (Zhao and Duncan, 1997 and 1998 and Davis and Volesky, 2003) which is written as:

qe =Qmax bCe / (1+ bCe )

where qe is the concentration of metals in the sorbent phase viz. biomass (mmol/g dry biomass), Ce is the equilibrium metals concentration or unadsorbed (mM.) that is obtained at the end of biosorption process. Qmax (mmol/g dry biomass) and b (1/mM) are the maximum adsorption capacity and a measure of adsorption energy and/or the sorption binding constant, respectively.

Langmuir equation transforms to the linearized form:

Ce/qe =Ce/Qmax +1/ (Qmax .b)

that Qmax and b are found from the slop and intercept of Ce/qe vs. Ce linear plot such that Qmax =slope-1 and b = (intercept -1.slope). qe is given from the following relation (Arica, et al., 2003):

qe = (Co – Ce) / Biomass dose

where Co is the initial concentration of the metal ions (mM) that is provided from 0.38 to 4.6 mM.

and biomass dose is 2g/l in this study. As can be seen from Figures 3a and 3b, the removal percentages by wetland Azolla are less than those for rice field Azolla. This reduces of the removal percentages were about of between 23–27 % for the initial concentrations of 1mM for each ion.

Table 1a, and b, shows the values of Qmax, b and correlation (r2) for the biosorption of heavy metals by the rice field and Anzali International Wetland Azolla.

Recovery of heavy metals from Azolla

The effect of two desorbents (HCl and NaCl) was studied. The desorption of metal ions was carried out from each 2 g. of rice field Azolla, which had been used in the biosorption of heavy metals with Co 1mM., in this study. It was performed by 300 ml. HCl and NaCl (0.2 M.) for 6 h. in a batch system, separately. The recovery percentage is obtained from the following relation (Zhao, et al., 1999 and Arica, et al., 2003):

Recovery (%) = (Desorbed / Adsorbed) 100

that the “desorbed” is the concentration and/or the mass of metal ions after the desorption and the “adsorbed” is equal to (Co–Ce) and/or (mo–me) for each recovery process. mo and me are the heavy metals mass in the aqueous solution, before and after the biosorption, respectively.

As can be seen from Table 2, the recovery of heavy metals by the both desorbents from Azolla was performed the following arrangement: Zn2+ > Cu2+ > Cd2+ > Pb2+. It was occurred by 0.2 M. HCl about 86%, 73%, 72% and 64%, respectively. While the recovery of these metal ions by 0.2 M. NaCl was occurred about 72%, 62%, 60% and 51%, respectively.

Discussion and Conclusion

The removal of heavy metal ions (Pb2+, Cd2+, Cu2+ and Zn2+) by collected Azolla filiculoides in the batch experiment in the fixed Azolla dose depends on the treatment conditions of biomass and the biosorption process. In the treatment of Azolla, the kind of activator material (mineral and oxidant agents) and activation pH were important. The best removal results were obtained when Azolla was treated by 2 M. MgCl2 and 30 ml. H2O2 8 mM. at pH 7 for 12 h. and it was then washed by NaOH solution at pH 10.5 for 6 h. pHs 5.5, 6, 5.5 and 6.7 for the biosorption of Pb2+, Cd2+, Cu2+ and Zn2+ were obtained as the optimal values, respectively. The maximum uptake capacities (Qmax) of Pb, Cd, Cu and Zn ions by the rice field Azolla filiculoides in the optimal conditions were about 228, 86, 62 and 48 mg/g (dry Azolla), respectively (Table 1a, and b). For instance, Qmax for Cd2+ and Cu2+ in the one of the studies by a biomass adsorbent in the batch biosorption were approximately 53 and 36 mg/g (dry biomass), respectively (An Ong, et al., 2005).

In compared with the values of Qmax in this study is appeared that the treated rice field Azolla with H2O2/MgCl2 can be considered as a biomass with the suitable ability for biosorption among of other types of biomass.

Figure 3b shows adsorption isotherms of Pb, Cd, Cu and Zn ions by the wetland Azolla. The obtained Qmax values for these heavy metals by the Anzali Wetland Azolla in the same conditions were about 124, 58, 33 and 34 mg/g (dry Azolla). The considerable difference between the obtained Qmax values by wetland Azolla with the obtained Qmax values by rice field Azolla can be evaluated because of the pollution of wetland mater due to discharging the kinds of wastewater to the Caspian Sea and the Anzali Wetland. Consequently the uptake capacity of heavy metals by Azolla is reduced by reason of the adsorption of wastewater contaminants. The study of heavy metals recovery shows that the ability of proton in the exchanging and recovery is more than Na+.

Acknowledgements

The authors are grateful to the Gilan province research center of bony fishes, Dr. M. Arvand and Dr. M. Rabbani.

References

  • Antunes, P. M., G. M. Watkins and J. R. Duncan, Batch studies on the removal of gold (III) from aqueous solution by Azolla f. G. M .iliculoides. Biotechnology letters, 23: 249-251, 2001
  • An Ong, S., P. Eng Lim, C. Eng Seng, M. Hirata and T. Hano, Effect of Cu (II) and Cd(II) performance of sequencing batch reactor treatment system. Process biochemistry, 40: 453-460, 2005
  • Arica, M. Y., C. Arpa and B. Kaya, Comparative biosorption of mercuric ions from aquatic systems by immobilized live and heat-inactivated trametes versicolor and pleurotus sajur-caju. Bioresource technology, 89: 145-154, 2003
  • Ashton, P. J. and R. D. Walmsley, The aquatic ferm Azolla and Anabaena symbiot. Endeavour, 35: 39-45, 1976
  • Cohen-Shoel, N., Z. Barkay and I. Gilath, Biofiltration of toxic elements by Azolla biomass. Water, air, and soil pollution, 135: 93-104, 2002a
  • Cohen-Shoel, N., D. Ilzycer and I. Gilath, The involvement of pectin in Sr (II) biosorption by Azolla. Water, air, and soil Pollution, 135: 195-205, 2002b
  • Donmez, G., Z. Aksu and A. Ozturk, A comparative study on heavy metal biosorption characteristics of some algae. Process biochemistry, 34: 885-892, 1999
  • Davis, T. A. and B. Volesky, A review of the biochemistry of heavy metal biosorption by brown algae. Water research, 37: 4311-4330, 2003
  • Feng, D. and C. Aldrich, Adsorption of heavy metals by biomaterials derived from the marine Ecklonia maxima. Hydrometallurgy, 73: 1-10, 2003
  • Fourest, E., C. Canal and J. C. Roux, Improvement of heavy metal biosorption by mycelial dead biomass (Rhizopus arrhizus, Mucor miechei and Pencillium chrysogenum): pH control and cationic activation. FEMS Microbial. Rev, 14: 325-332, 1994
  • Iijima, M., T. Hatakeyama and K. Nakamura, Effect of annealing on calcium pectin gel formation by thermo mechanical analysis. Journal of thermal analysis and calorimetry, 70: 815-824, 2002
  • Jauneau, A., M. Quentin and A. Driouich, Micro – Heterogeneitly of pectins and calcium distribution in the epidermal and cortical parenchyma cell wall of flax hypocotyl. Protoplasma, 189: 9-19, 1997
  • Kamnev, A. A., M. Colina and J. Rodriguez, Comparative spectroscopic characterization of different pectin’s and their source. Food Hydrocolloids, 12: 263271, 1998
  • Kaewsarn, P., Biosorption of copper (II) from aqueous solutions by pre-treated biomass of marine algae Padina sp. Biosorption of Chemosphere, 47: 1081-1085, 2002
  • Matheickal, J. T. and Q. Yu, Biosorption of lead (II) and copper (II) from aqueous solutions by pre-treated biomass of Australian marine algae. Bioresource technology, 69: 223-229, 1999
  • Matheickal, J. T. and Q. Yu, Biosorption of lead (II) from aqueous solutions by Phellinus badius. Miner. Eng., 10: 947-957, 1997
  • Muraleedharan, T. R., L. Iyengar and L. Venkobachar, Screening of tropical wood-rotting mushrooms for copper biosorption. Appl. Environ. Microbial, 61: 35073508, 1995
  • Niu, H., X. S. Xu and J. H. Wang, Removal of lead from aqueous solutions by Penicilium biomass. Biotechnol. Bioeng. 42: 785-787, 1993
  • Ozdemi, G., T. Ozturk and A. Ceyhan, Heavy metal biosorption by biomass of Ochrobactrum anthropi producing exopolysaccharide in activated sludge. Bioresource technology, 90: 71-74, 2003
  • Pacoda, D. and A. Montefusco, Reactive oxygen species and nitric oxide affect cell wall metabolism in tobacco by-2 cell. Journal of plant physiology, 161: 1143-1156, 2004
  • Peters, G. A. and J. C. Meeks, The Azolla-Anabaena symbiosis: basic biology. Ann. Rev. Plant Physiol. Plant Mol. Biol, 40: 193-210, 1989
  • Robert, R. and S. Barbati, Intermediates in wet oxidation of cellulose: identification of hydroxyl radical and characterization of hydrogen peroxide. Water research, 36: 4821-4829, 2002
  • Sanyahumbi, D., J. R. Duncan and M. Zhao, Removal of lead from solution by the non-viable biomass of the water fern Azolla filiculoides . Biotechnology letters, 20 (8): 745-747, 1998
  • Spearot, R. M. and J. V. Peck, Recovery process for complexed copper-bearing rinse. Waters Environ. Prog, 3: 124-129, 1984
  • Shao, P. L. and Z. Kuij, A polysaccharide isolated from Cordyceps Sinensis, a traditional Chinese medicine, protects PCl2 cells against hydrogen peroxide-induced injury. Life sciences, 73: 2503-2513, 2003
  • Volesky, B., Biosorption of heavy metals. CRC Press, Boca Raton, USA. 1990
  • Volesky, B., Advances in biosorption of metals: selection of biomass types. FEMS microbial. Rev, 14: 291-3029, 1994
  • Volesky, B., H. May and Z. Holan, Cadmium biosorption by Saccharomyces cerevisiae. Biotechnol, 41: 826-829, 1993
  • Zhao, M., J. R. Duncan and R. P. Van Hille, Removal and recovery of zinc from solution and electroplating effluent using Azolla Filiculoides. Wat. Res, 33 (6): 15161522, 1999
  • Zhao, M. and J. R. Duncan, Batch removal of hexavalent chromium by Azolla filiculoides . Appl. Biochem. Biotechnol, 26, 179-183, 1997
  • Zhao, M. and J. R. Duncan, Removal and recovery of nickel from solution and electroplating rinse effluent using Azolla filiculoides . Process biochemistry, 33 (3): 249-255, 1998

© 2004 Center for Environment and Energy Research and Studies (CEERS)


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