Grain Size Effect on Durability of Bioclogging Treatment
Authors: T. Farah, H. Souli, J. –M. Fleureau, G. Kermouche, J. –J. Fry, B. Girard, D. Aelbrecht
Abstract:
In this work, the bioclogging of two soils with different granulometries is presented. The durability of the clogging is also studied under cycles of hydraulic head and under cycles of desaturation-resaturation. The studied materials present continuous grain size distributions. The first one corresponding to the "material 1” presents grain sizes between 0.4 and 4mm. The second material called "material 2" is composed of grains with size varying between 1 and 10mm. The results show that clogging occurs very quickly after the injection of nutrition and an outlet flow near to 0 is observed. The critical hydraulic head is equal to 0.76 for "material 1", and 0.076 for "material 2". The durability tests show a good resistance to unclogging under cycles of hydraulic head and desaturation-resaturation for the "material 1". Indeed, the flow after the cycles is very low. In contrast, "material 2", shows a very bad resistance, especially under the hydraulic head cycles. The resistance under the cycles of desaturation-resaturation is better but an important increase of the flow is observed. The difference of behavior is due to the granulometry of the materials. Indeed, the large grain size contributes to the reduction of the efficiency of the bioclogging treatment in this material.
Keywords: Bioclogging, Granulometry, permeability, nutrition.
Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1090819
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[1] G. A. James, B. K. Warwood, R Hiebert and A. B. Cunningham "Microbial barriers to the spread of pollution”. In: Bioremediation. Kluwer Academic, Amsterdam, 2000, pp. 1–14
[2] K. Seki, M. Thullner, T. Miyazaki "Moderate bioclogging leading to preferential flow paths in biobarriers”, Ground Water Monitor. Remed. Vol. 26, pp. 68–76, 2006.
[3] V.M. van Beek, D. den Hamer, J.W.M. Lambert, M.N. Latil and W.H. van der ZonBiosealing a natural sealing mechanism that locates and repairs leaks in Proc. of the 1st Int. Conf. on Self Healing Materials Noordwijk an Zee, The Netherlands, 18-20 April, 2007,
[4] H. Bouwer "Artificial recharge of groundwater hydrogeology and engineering”, Hydrogeol J., vol. 10, pp. 121–142, 2002.
[5] P. Baveye and A. Valocchi, "An evaluation of mathematical models of the transport of biologically reacting solutes in saturated soils and aquifers”, Water Resour. Res. Vol. 25, pp. 1413–1421, 1989.
[6] P. Baveye, P. Vandevivere, B. Hoyle, P. DeLeo and D.S. Lozada, "Environmental impact and mechanisms of the biological clogging of saturated soils and aquifer materials”, Crit. Rev. Env. Sci. Tech. vol. 28, pp. 123–191, 1998.
[7] D. Seifert and P. Engesgaard "Use of tracer tests to investigate changes in flow and transport properties due to bioclogging of porous media”, J. Contam. Hydrol. Vol. 93, pp. 58–71, 2007.
[8] SR. Ragusa, D.S. de Zoysa, and P. Rengasamy"The effect of microorganisms, salinity and turbidity on hydraulic conductivity of irrigation channel soil”, Irrigation Sci., vol. 15, pp. 159–166, 1994.
[9] P. Vandevivere and P. Baveye,” Effect of bacterial extracellular polymers on the saturated hydraulic conductivity of sand columns”, App. Env. Microbiol., Vol. 58, pp 1690–1698, 1992.
[10] A. B. Cunningham, W. G. Charaklis, F. Abedeen and D. Crawford, "Influence of biofilm accumulation on porous media hydrodynamics”, Environ. Sci. Technol., vol.25, pp. 1305–1311, 1991.
[11] M. J. Brough, A. Al-Tabbaa and R. J. Martin, "Active biofilm barriers for waste containment and bioremediation: laboratory assessment,” in: Proc. Int. Symp. In Situ and On-site Bioremediation, New Orleans, USA, May, 1997, pp. 233–238,
[12] D. S. Kim and H. S. Fogler "Biomass evolution in porous media and its effects on permeability under starvation conditions”, Biotech. And Bioeng., vol. 69, pp. 47-56, 2000.
[13] K. Seki, T. Miyazaki and M. Nakano "Effects of microorganisms on hydraulic conductivity decrease in infiltration”, Eur. J. Soil Sci. vol. 49, pp. 231–236, 1998.
[14] X. Zhong and Y. Wu, "Bioclogging in porous media under continuous-flow condition”, Environ Earth Sci. vol. 68, pp 2417–2425, 2013.
[15] J. Wu, Y. Wu, J. Lu and L. Lee, "Field investigations and laboratory simulation of clogging in Lixi tailings dam of Jinduicheng, China”, Environ. Geol., vol. 53, pp 387-397, 2007.
[16] P. Baveye and A: Dumestre, "Comments on: experimental study on the reduction of soil hydraulic conductivity by enhanced biomass growth”, Soil Sci. vol.163, pp. 759–761, 1998.
[17] T.P. Clement, B.S. Hooker, R.S. Skeen, "Macroscopic models for predicting changes in saturated porous media properties caused by microbial growth”, Ground Water, vol. 34, pp. 934–942, 1996.
[18] P. Vandevivere, P. Baveye, D. Lozada and P. DeLeo, "Microbial clogging of saturated soils and aquifer materials: evaluation of mathematical models”, Water Resour. Res., vol. 31, pp. 2173–2180, 1995.
[19] C. Loehle, and P. Johnson A framework for modeling microbial transport and dynamics in the subsurface, Ecol. Model., vol. 73, pp. 31–49, 1994.
[20] A. Brovelli, X. Mao and D.A. Barry, "Numerical modeling of tidal influence on density-dependent contaminant transport”, Water Resour. Res., vol. 43, W10426, 2007.
[21] M. Thullner, J. Zeyer and W. Kinzelbach.” Influence of microbial growth on hydraulic properties of pore networks”,Transp. Porous Media, vol. 49, pp. 99–122, 2002.
[22] V.L. Hand, J.R. Lloyd, D.J. Vaughan, M.J. Wilkins andS.Boult, "Experimental studies of the influence of grain size, oxygen availability and organic carbon availability on bioclogging in porous media”, Environ. Sci. Technol., vol. 42, pp. 1485-1491, 2008.
[23] P. Vandevivere and P. Baveye, "Saturated hydraulic conductivity reduction caused by aerobic bacteria in sand columns”,Soil Sci. Soc. Am. J., vol. 56, pp.1 –13, 1992.
[24] A.R. Bielefeldt, T. Illangasekare, M. Uttecht and R. La Plante, Biodegradation of propylene glycol and associated hydrodynamic effects in sand. Water Res. vol. 36, pp. 1707–1714, 2002.
[25] A. Paksy, W. Powrie, J.P. Robinson, and L. Peeling, "A laboratory investigation of anaerobic microbial clogging in granular landfill drainage media”,Geotechnique, vol. 48, pp. 389–401, 1998.
[26] A.J. Cooke, R.K. Rowe, J Van Gulck, B.E. Rittmann "Application of the BioClog model for landfill leachate clogging of gravel packed columns”, Can Geotech J vol. 42, pp. 1600–1614, 2005.