Abstract
In this project, an in situ soil treatment technique using the principles of electrokinetics was tested using laboratory experimental models in order to identify the potential of this approach in modifying and reinstating the physical properties of salt affected soils. Experiments were conducted in the laboratory using saline-sodic soils collected from two salt affected regions in central Victoria, Australia. Soil specimens were compacted in glass tanks to reproduce in situ density and in situ water content. Using mild steel electrodes inserted into the soil, a direct current was passed through the soil under a constant potential gradient of 0.5 V/cm for a period of 14 days. In separate experiments, distilled water and a saturated lime solution were introduced to the soil via the anode over this experimental period. It was observed that the soil dispersion, otherwise known as soil sodicity (measured as ESP—Exchangeable Sodium Percentage and SAR—Sodium Absorption Ratio) decreased by up to 90% in most regions of the soil between the electrodes. The compressive strength of the soil increased in excess of 100% with electrokinetic treatment alone while the lime-enhanced electrokinetic treatment led to an almost 200% strength increase. The liquid limit and plastic limit of the soil increased causing the plasticity index to decrease, indicating increases in soil compressive strength and workability. These results indicate the potential of this technique for improving the physical properties of salt affected soils both effectively and efficiently, and in particular gives hope for the remediation of salt affected land for infrastructure management and development.
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References
Abdullah WS, Al-Abadi AM (2005)“Implementation of the electrokinetic processes as an effective method for soil improvement.” International conference on problematic soils GEOPROB 2005, Famagusta, N. Cyprus, pp 885–894
Acar YB, Alshawabkeh AN (1993) Principles of electrokinetic remediation. Environ Sci Technol 27(13):2638–2647
Acar YB, Alshawabkeh AN (1996) Electrokinetic remediation. I. Pilot-scale tests with lead spiked kaolinite. J Geotech Eng 122(3):173-185
Acar YB, Gale RJ, Putnam G (1990) Electrochemical processing of soils: Theory of pH gradient development by diffusion and linear convection. J Environ Sci and Health 25(6):687–714
Acar YB, Hamed JT, Alshawabkeh AN, Gale RJ (1994) Removal of cadmium (II) from saturated kaolinite by the application of electrial current. Geotechnique 44(2):239–254
Bergado DT, Balasubramaniam AS, Patawaran MAB, Kwunpreuk W (2000) Electro-osmotic consolidation of soft Bangkok clay with fabricated vertical drains. Ground Improvement 4:153–163
Casagrande L (1951) Electro-osmotic stabilization of soils. Transactions of Boston Society of Civil Engineers 39: 51–83.
Chappell BA, Burton PL (1975) Electro-osmosis applied to unstable embankment. J Geotech Eng Div 101(8): 733–739
Chappell BA, Huggins G (1998) Effect of backfill strength and stiffness on slope stability. AusIMM’98—The Mining Cycle, Mount Isa, Australia, pp 213–217
CSIRO (2003) Salinity. Commonwealth Scientific and Industrial Research Organisation:Land and water, Australia
Ewers B, Smith D, Fityus S (2002) Electro-osmotic testing of Ballina clay. Environmental Geomechanics, Monte Verita, Switzerland, pp 295–301
Eykholt GR, Daniel DE (1994) Impact of system chemistry on electroosmosis in contaminated soil. J Geotech Eng 120:797–814
Halliwell DJ, Barlow KM, Nash DM (2001) A review of the effects of wastewater sodium on soil physical properties and their implications for irrigation systems. Aus J Soil Res 39:1259–1267
Hamed JT, Acar YB, Gale RJ (1991) Pb(II) removal from Kaolinite by electrokinetics. J Geotech Eng 117(2):241–271
Jayasekera S (2004) Electroosmotic and hydraulic flow rates through kaolinite and bentonite clays. Aus Geomech 39(2):79–86
Jayasekera S, Hall S (2005) Lime enhanced electrokinetic treatments to modify the properties of a saline-sodic soil International Conference on problematic soils: GEOPROB 2005, Famagusta, N. Cyprus, pp 913–923
Jayasekera S, Mewett J, Hall S (2004) Effects of electrokinetic treatments on the properties of a salt affected soil. Aus Geomech 39(4):33–46
Johnston IW, Butterfield R (1977) A laboratory investigation of soil consolidation by electro-osmosis. Aus Geomech G7:21–32
Kennedy TW, Smith RJ, Holmgreen RJ, Tahmoressi M (1987) An evaluation of lime and cement stabilisation Transportation research record 1110, TRB
Lageman R (1993) Electroreclamation: application in the Netherlands. Environ Sci Technol 27(13):2648–2650
Lageman R, Pool W, Seffinga GA (1990) Electroreclamation: state of the art and future developments. Contaminated soil ’90, pp 1071–1078
McRobert J, Houghton N, Styles E (2003) Salinity impact and roads-towards a dialoge between climate change and groundwater modellers. Road Transport Res 12(3):45–60
Pamukcu S (1997) Electrochemical technologies for in-situ restoration of contaminated subsurface soils. Electron J Geotech Eng 2:1–34
Pamukcu S, Weeks A, Wittle JK (1997) Electrochemical extraction and stabilization of selected inorganic species in porous media. J Hazard Mater 55:305–318
Pamukcu S, Wittle JK (1992) Electrokinetic removal of selected heavy metals from soil. Environ Prog 11(3):241–250
Reddy KR, Saichek RE (2004) Enhanced electrokinetic removal of phenanthrene from clay soil by periodic electric potential application. J Environ Sci Health A 39(5):1189–1212
Reddy KR, Shirani AB (1997) Electrokinetic remediation of metal contaminated glacial tills. Geotech Geol Eng 15: 3–29
Rogers CDF, Liaki C, Boardman DI (2003) Advances in the engineering of lime stabilised clay soils. International Conference on Problematic Soils, Nottingham, UK
Sadrekarimi J (2005) Effects of pH and duration on the electro-osmotic treatment of dispersive soils. International Conference on Problematic soils, GEOPROB 2005, Famagusta, N. Cyprus, pp 785–792
Sadrekarimi J, Sadrekarimi A Voltage and duration effects of electroosmotic treatment of dispersive soils. An International Conference on Problematic Soils, Nottingham, UK, pp 453–457
Salt Force (1998) Salt Action: Joint Action, Victoria’s strategy for managing land and water salinity Government of Victoria
Shariatmadari N, Garga VK, Falamaki A (2001) Phenol removal from contaminated clay by electrokinetics. Geoenvironment 2001, New Castle, NSW, Australia, 501–506
Sherwood P (1993) Soil stabilisation with cement and lime, State of the art review. Longman publishers, London
Slavich PG, Petterson GH (1993) Estimating the electrical conductivity of saturated paste extracts from 1:5 soil:water suspensions and texture. Aus J Soil Res 31:73–81
Ugaz A, Puppala S, Gale RJ, Acar YB (1994) Electrokinetic soil processing: complicating features of electrokinetic remediation of soils and slurries: saturation effects and the role of the cathode electrolysis. Chem Eng Comm 129:183–200
van de Graaff R, Patterson RA (2001) Explaining the mysteries of salinity, sodicity, SAR and ESP in on-site practice. On-site 01, Advancing on-site wastewater systems, Armidale, NSW, Australia 361–368
West LJ, Stewart DI (2000) Effect of zeta potential on soil electrokinetics. Geoenvironment 2000 1535–1549
Acknowledgements
The results presented in this paper are part of an on going project being carried out at the School of Science and Engineering of the University of Ballarat. The first author is supported by the University of Ballarat’s early career research funding scheme and an Australian Postgraduate Award (APA).
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Jayasekera, S., Hall, S. Modification of the properties of salt affected soils using electrochemical treatments. Geotech Geol Eng 25, 1–10 (2007). https://doi.org/10.1007/s10706-006-0001-8
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DOI: https://doi.org/10.1007/s10706-006-0001-8