Phenol Removal Using Granular Dead Anaerobic Sludge Permeable Reactive Barrier in a Simulated Groundwater Pilot Plant

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Ayad Abdulhamza Faisal
Ziad Tark Abd Ali

Abstract

This study investigates the performance of granular dead anaerobic sludge (GDAS) bio-sorbent as permeable reactive barrier in removing phenol from a simulated contaminated shallow groundwater. Batch tests have been performed to characterize the equilibrium sorption properties of the GDAS and sandy soil in phenol-containing aqueous solutions. The results of GDAS tests proved that the best values of operating parameters, which achieve the maximum removal efficiency of phenol (=85%), at equilibrium contact time (=3 hr), initial pH of the solution (=5), initial phenol concentration (=50 mg/l), GDAS dosage (=0.5 g/100 ml), and agitation speed (=250 rpm). Fourier transform infrared (FTIR) analysis proved that the carboxylic acid, aromatic, alkane, alcohol, and alkyl halides groups are responsible for the bio-sorption of phenol onto GDAS.
A 2D advection-dispersion, solved numerically by computer solutions (COMSOL) Multiphysics 3.5a software which is based on the finite element method, has been used to simulate the equilibrium transport of phenol within groundwater. This model is taking into account the pollutant sorption onto the GDAS and sandy soil which is represented by Langmuir equation. Numerical and experimental results proved that the barrier plays a potential role in the restriction of the contaminant plume migration. Also, the barrier starts to saturate with contaminant as a function of the travel time. A good agreement between the predicted and experimental results was recognized with root mean squared error not exceeded the 0.055.

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How to Cite

“Phenol Removal Using Granular Dead Anaerobic Sludge Permeable Reactive Barrier in a Simulated Groundwater Pilot Plant” (2014) Journal of Engineering, 20(11), pp. 63–79. doi:10.31026/j.eng.2014.11.05.

References

 Ambrosini, G. S. D., 2004, Reactive Materials for Subsurface Remediation through Permeable Reactive Barriers, Ph.D. Thesis, Swiss Federal Institute of Technology Zurich.

 Anderson, M. P., and Woessner, W. W., 1992, Applied Groundwater Modeling: Simulation of Flow and Advective Transport, 2nd Edition, Academic Press.

 Chen, J. P., Wang, L., and Zou, S. W., 2008, Determination of Lead Bio-Sorption Properties by Experimental and Modeling Simulation Study, Chem. Eng. J., Vol. 131, PP. 209-215.

 Doke, K. M., Yusufi, M., Joseph, R. D., and Khan, E. M., 2012, Bio-Sorption of Hexavalent Chromium onto Wood Apple Shell: Equilibrium, Kinetic and Thermodynamic Studies, Desalination and Water Treatment, Vol. 50, PP. 170-197.

 El-Sayed, G. O., Dessouki, H. A., and Ibrahim, S. S., 2010, Bio-sorption of Ni(II) and Cd(II) Ions from Aqueous Solutions onto Rice Straw, Chem. Sci. J., CSJ-9.

 Gillham, R. W., and Burris, D. R., 1992, Recent Developments in Permeable In-Situ Treatment Walls for Remediation of Contaminated Groundwater, Proc. Subsurface Restoration Conference, Dallas, Texas. June 21-24.

 Hamdaouia, O., and Naffrechoux, E., 2007, Modeling of Adsorption Isotherms of Phenol and Chlorophenols onto Granular Activated Carbon Part I. Two-Parameter Models and Equations Allowing Determination of Thermodynamic Parameters, Journal of Hazardous Materials, Vol. 147, PP. 381–394.

 Mathews, A., and Zayas, I., 1989, Particle Size and Shape Effects on Adsorption Rate Barameters, Journal of Environ. Eng., Vol. 115, No. 1, PP. 41–55.

 Mieles, J., and Zhan, H., 2012, Analytical Solutions of One-Dimensional Multispecies Reactive Transport in a Permeable Reactive Barrier-Aquifer System, Journal of Contaminant Hydrology, Vol. 134-135, PP. 54-68.

 Powell, W. W., Kenneth, W., Koput, J., Bowie, I., and Laurel S. D., 2002, The Spatial Clustering of Science and Capital: Accounting for Biotech Firm – Venture Capital Relationships, Regional Studies, Vol. 36, No. 3, PP. 299-313.

 Suponik, T., 2010, Adsorption and Biodegradation in PRB Technology, Environmental Protection Eng., Vol. 36, PP. 43-57.

 Teerakun, M., Reungsang, A., Lin, C. J., and Liao, C. H., 2011, Coupling of Zero Valent Iiron and Bio-Barriers for Remediation of Trichloroethylene in Groundwater, Journal of Environmental Sciences, Vol. 23, PP. 560–567.

 Ujfaludi, L., 1986, Longitudinal Dispersion Tests in Non-uniform Porous Media, Hydrological Sciences Journal - des Sciences Hydrologiques, Vol. 31, No. 4, PP. 467-474.

 Wang, S., Nan, Z., Li, Y., and Zhao, Z., 2009, The Chemical Bonding of Copper Ions on Kaolin from Suzhou, China, Desalination, Vol. 249, PP. 991–995.

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