An Investigation into the Efficiency of the Modified Sawdust and Rice Bran in Treating the Polluted Aqueous Solutions with Cr (VI)

Document Type : Research Paper

Authors

1 Ph.D. candidate of Soil Science (Soil chemistry and fertility) Department, Isfahan (Khorasgan) Branch, Islamic Azad University, Isfahan, Iran.

2 Department of Soil sciences (soil chemistry and fertility), Islamic Azad University of Khorasgan

3 3. Soil and Water Research Department, Fars Agricultural and Natural Resources Research and Education Center, AREEO, Shiraz, Iran.

4 Department of Soil Sciences (Soil chemistry and fertility), Isfahan (Khorasgan) Branch, Islamic Azad University, Isfahan, Iran.

Abstract

Abstract
Introduction: This study investigated the possibility and efficiency of absorbing Cr (VI) ions from the polluted water by employing the chemically modified natural adsorbents of sawdust and rice bran. For each adsorbent three chemical modifications were considered (i.e., acid, biochar and alkali) and the impacts of various adsorbents’ pH values, dosages, concentrations and contact times were studied.
Methods: The colorimetric method using UV/VIS spectrophotometer was used for Cr determination. Moreover, for analyzing the characteristics of the modified adsorbents, the “Scanning Electron Microscope” and “Fourier-Transform Infrared Spectroscopy” were utilized.
Findings: It was found that the acid sawdust and rice bran had functioned better than the other chemical modifications. In fact, the highest efficiency of Cr (IV) adsorption from the polluted aqueous solutions occurred at pH 2, contact-time of 100 minutes, Cr concentration of 50 mg/L and adsorbent dosage of 2 g/L by acid sawdust (96.73%), biochar sawdust (95.60%), acid rice bran (94.50%), biochar rice bran (94.27%), alkali sawdust (92.36%) and alkali rice bran (88.6%), respectively. The adsorption kinetics was agreeably suited to the equations of pseudo second order while the Freundlich isotherm equation was also suitably expounded the study’s findings. The findings depicted that the acid and biochar sawdust and rice bran better than the alkali ones, performed remarkably in the remediation of the wastewater. This would result in the wastewater treatment and its reuse for industrial, agricultural and environmental purposes.

Keywords

References

1.       Montanher, S., Oliveira, E., Rollemberg, M. 2005. Removal of metal ions from aqueous solutions by sorption onto rice bran. Journal of Hazardous Materials. 17: 207-211.

2.       Almasi, A., Dargahi, A., Ahagh, M., Janjani, H., Mohammadi, M., Tabandeh, L. 2016. Efficiency of a constructed wetland in controlling organic pollutants, nitrogen, and heavy metals from sewage. Journal of chemical and pharmachological sciences. 9: 2924-2928.

3.       Alavi, S., Shamshiri, S., Pariz, Z., Dargahi, A., Mohamadi, M., Fathi, S., Amirian, T. 2016. Evaluating the palm leaves efficiency as a natural adsorbent for removing cadmium from aqueous solutions: Isotherm adsorption study. International Journal of Pharmacy and Technology. 8: 13919-13929.

4.       Esfahani, A.R., Zhang, Z., Sip, Y.L., Zhai, L., Sadmani, A. 2020. Removal of heavy metals from water using electrospun polyelectrolyte complex fiber mats. Journal of Water Protecting Engineering. 37: 101-138.

5.       Dargahi, A., Golestanifar, H., Darvishi, P., Karam, A. 2015. An investigation and comparison of removing heavy metals (lead and chromium) from aqueous solutions using magnesium oxide nanoparticles. Polish Journal of Environmental studies. 25(2): 557-563. 

6.       Wang, Z., He, Z. 2020. Frontier review on metal removal in bioelectrochemical systems: mechanisms, performance, and perspectives. Journal of Hazardous Materials 56: 100-112.

7.       Munyengabe, A., Zvinowanda, C.Z., vimba, J.N., Ramontja, J. 2020. Innovative oxidation and kinetic studies of ferrous ion by sodium ferrate (VI) and simultaneous removal of metals from a synthetic acid mine drainage. Physics and Chemistry of the Earth. 56: 102-132.

8.       Tahir, N., Bhatti, H. N., Iqbal, M., Noreen, S. 2017. Biopolymers composites with peanut hull waste biomass and application for Crystal Violet adsorption. International Journal of Biological Macroscopy. 94: 210-220.

9.       Butt, H., Graf, K., Kappl, M. 2003. Physics and Chemistry of Interfaces. 1st Ed. USA: Wiley Publications.: pp.76-89.

10.   Samadani Langeroodi, N., Tahery, F., Mehrani, S. 2015. Thermodynamic and kinetic investigation of citric acid adsorption by rice bran. Nova Biological Report. 2: 166-175.

11.   Bhatti, H.N., Jabeen, A., Iqbal, M., Noreen, D.S., Naseem, Z. 2017. Adsorptive behavior of rice bran-based composites for malachite green dye: isotherm, kinetic and thermodynamic studies, Journal of molecular liquids. 23 (7): 322-333.http://dx.doi.org/10.1016%2Fj.molliq.2017.04.033

12.   Wanngah, W.S., Hanafiah, M.A. 2008. Removal of heavy metal ions from wastewater by chemically modified plant wastes as adsorbents: a review. Biological Technology. 99: 3935-3948.

13.   Acharya, J., Kumar, U., Rafi, P.M. 2018. Removal of Heavy Metal Ions from Wastewater by Chemically Modified Agricultural Waste Material as Potential Adsorbent-A Review. International Journal of Current Engineering and Technology. 8(3): 526-530.

14.   Bansal, M., Garg, U.,  Diwan, S., Garg, V.K. 2009. Removal of Cr (VI) from aqueous solutions using pre-consumer processing agricultural waste: A case study of rice husk. Journal of Hazardous Materials. 16: 312-320.

15.   Zhang, X., Zhang, L., Li, A. 2018. Eucalyptus sawdust derived bio-char generated by combining the hydrothermal carbonization and low concentration KOH modification for hexavalent chromium removal. Journal of Environmental Management. 20: 989-998.

16.   Elhami, S,, Bahadori, A. 2015. Using Modified Sawdust for Removal of Chromium (VI) from aqueous solutions. Biological Forum. 2015. 7(2): 47-51.

17.   Bijani, M.; Hayati, D., and Abdolvand, M. 2012. Conflict in water utilization in Dorodzan dam irrigation network (views of regional water experts). Environmental Sciences, 10(1): 59-78. [In Persian].

18.   Wang, H., Zhang, M., Qi, L. 2019. Removal efficiency and mechanism of chromium from aqueous solution by maize straw biochar derived from different pyrolysis temperatures. Water, 11(4): 781-794.

19.   Kim, K.H., Kim, J.Y., Cho, T.S., Choi, J.W. 2012. Influence of pyrolysis temperature on physicochemical properties of biochar obtained from the fast pyrolysis of pitch pine (Pinus rigida). Biological Technology. 11(8): 158-162.

20.   Davoudi, M., Alidadi, H., Mehrabpour, M., Dolatabadi, M. 2017. The Study of Efficacy of Sawdust Melia Azedarach for Dye & Heavy Metal Removal from Textile Industry Effluents. Journal of Health Souvenir. 3(2): 56-69.

21.   Singh, R., Misra, V., Singh, R.P. 2011. Synthesis, characterization and role of zero-valent iron nanoparticle in removal of hexavalent chromium from chromium-spiked soil. Journal of Nano Research.13:4063-4073.https://doi.org /10.1007/s11051-011-0350-y.

22.   Claoston, N., Samsuri, A. W., Husni, M.H., Amran, M.S. 2014. Effects of Pyrolysis temprature on the physicochemical properties of empty fruit bunch and rice husk biochars. Waste management and Research. 32: 331-342.

23.   Hosseini, S.M., Farrokhiyan, F.A., Babaei, A.A., Heidarzadeh, F. 2013. Removal of cu (ii) from aqueous solution by modified tea waste with magnetic nanoparticles. Journal of Water and Waste. 24(4): 112-119.

24.   Fu, W., Huang, Z. 2018. Magnetic dithiocarbamate functionalized reduced graphene oxide for the removal of Cu (II), Cd (II), Pb (II), and Hg (II) ions from aqueous solution. Synthesis, adsorption, and regeneration. Chemosphere. 20: 449-456.

25.   Chen, C., Zhao, P., Li, Z., Tong, Z. 2015. Adsorption behavior of chromium (VI) on activated carbon from eucalyptus sawdust prepared by microwave-assisted activation with ZnCl2. Water Treatment. 57: 12572-12584.

26.   Shakya, A., Nunez-Delgado, A., Agarwal, T.J. 2019. Biochar synthesis from sweet lime peel for hexavalent chromium remediation from aqueous solution. Journal of Environmental Management.  25: 1095-1111.

27.   Zhang, L., Song, X., Liu, X., Yang, L., Pan, F. 2011. Studies on the removal of tetracycline by multi-walled carbon nanotubes. Chemical Engineering Journal, 17:26-33.

28.   Kermani, M., Pourmoghaddas H, Bina, B., Khazaei, Z. 2006. Removal of phenol from aqueous solutions by rice husk ash and activated carbon. Pakistanian Journal of Biological Sciences. 9: 1905-1910.

29.   Sarin, V., Pant, K. 2006. Removal of chromium from industrial waste by using eucalyptus bark. Bioresource Technology. 97: 15-20.

30.   Wu, J., Yu, Q. 2006. Biosorption of 2, 4-dichlorophenol from aqueous solution by Phanerochaete chrysosporium biomass: Isotherms, kinetics and thermodynamics. Journal of hazardous materials. 13: 498-508.

31.   Entezari, A., Khosravi, R., Arghavan, F., Taghizadeh, A., Khodadadi, M., Eslami, H. 2016. Investigation of hexavalent chromium removal from aqueous solution using granular and powdered activated carbon produced from peganum harmala seed. Journal of Rafsanjan University of Medical Sciences. 15: 645-656.

32.   Seidmohammadi, A., Asgari, G., Dargahi, A., Leili, M., Vaziri, Y., Hayati, B., Shekarchi, A., Mobarakian, A., Bagheri, S., Nazari Khanghah, A. 2019. Comparative study for the removal of Methylene blue dye from aqueous solution by novel activated Carbon based adsorbents. Progress in Color, Colorants and Coatings. 12: 133-144.

33.   Georgieva, V.G., Tavlieva, M.P., Genieva, S.D., Vlaev, L.T. 2015. Adsorption kinetics of Cr (VI) ions from aqueous solutions onto black rice husk ash. Journal of Molecular Liquids. 20: 219-226.

Water Resources Engineering
Volume 15, Issue 55 - Serial Number 55
February 2022
Pages 91-104

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History

  • Receive Date: 08 August 2021
  • Revise Date: 01 October 2021
  • Accept Date: 19 February 2023

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