Permeability of Expansive Soils Modified/Stabilized with lime (Review Paper)

https://doi.org/10.24237/djes.2021.14212

Authors

  • Muwafaq Awad Department of Civil Engineering, College of Engineering, University of Mosul
  • Ibrahim Al-Kiki Department of Dams and Water Resources Department, College of Engineering, University of Mosul
  • Amina A Khalil Department of Civil Engineering, College of Engineering, University of Mosul

Keywords:

Permeability, Lime modification / stabilization, Expansive soils

Abstract

The aim of this paper was to review the mechanism of the expansive soil-lime reactions: short term and long-term reactions in both lime modification and lime stabilization. The focus of the study was the effect of curing time for a certain centigrade 25C curing temperature in both lime modification / stabilization-expansive soils on the coefficient of permeability. Peer reviewed articles published between 2000- and 2019 were collected and relevant data were extracted. Results of this review study showed that the coefficient of permeability of expansive soils modified with lime increased during the first 7 days of curing time at curing temperature 25C and it remains constant or slightly decreased for longer curing time periods. However, for expansive soils stabilized with lime, it was found that the coefficient of permeability increased during the first 7-day curing time at curing temperature 25C, then decreased during the longer curing time periods (pozzolanic reaction). It is also noted that even though the coefficient of permeability decreased during pozzolanic reaction, it remains higher than that of the untreated soils.

Conclusions

Based on the data selected from previous works, the following conclusions can be driven from this review paper:

  1. For lime modification, the initial consumption lime (ICL) is added to the expansive soil sand caused to increase the coefficient of permeability (k) during the first 7-day curing time at 25C curing temperature. Beyond the 7 days curing time, the coefficient of permeability may remain constant or slightly decreased.
  2. For lime stabilization, adding lime content to the expansive soils must be more than ICL. This percent of lime will attribute to increase the coefficient of permeability (k) for the first 7 days curing time. After that (longer curing time), the pozzolanic reaction will develop. The coefficients of permeability decreased and continue decrease as long as the pozzolanic reaction has been developing. But the final magnitude of the coefficient of permeability remains higher than that of the untreated soils even at very long curing time.
  3. High technologies such as Scanning electron microscopy (SEM) showed that the inter-particle pores are in charge of the change in the coefficient of permeability of lime modification/stabilization of expansive soils.
  4. An average value of increasing permeability for all studies at curing time 7 days and 28 days can be determined and its ratio to initial average value can be quantified to assess the amount of increasing in soil permeability at different stage.

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References

Holtz, R. D. and, Kovacs, W. D. (1981). An introduction to geotechnical engineering. Prentice hall, Englewood, New Jersey.

Li, J., Cameron, D. A., & Ren, G., (2014). Case study and back analysis of a residential building damaged by expansive soils. Computers & Geotechnics, 56, 89-99.

Jones, L. D., and Jefferson, I., 2012 Expansive soils Inst. of Civ. Eng. Pupl. London UK pp 413.

Chen, F., H., 1988 "Foundation on expansive soil Soils. Elsevier, Amsterdam, the Netherland.

Mohamed, A. K., (2013). Improvement of swelling clay properties using hay fibers. Construction & Materials 38, 242-247.

Al-Mukhtar, M., Lastedj, A. and, Alconer, J. (2010a). Behaviours and mineralogy changes in lime treated expansive soil at 20C. Applied Clay Science. 50 No. 2, 191-198.

Al-Mukhtar, M., Lastedj, A. and, Alconer, J. (2010b). Behaviours and mineralogy changes in lime treated expansive soil at 50C. Applied Clay Science. 50 No. 2, 199-203.

Afaf, A. H. M., Hesham, A. H. I., and Atef, M. A. (2013). Improvement of expansive subgrade by lime addition. Journal of Engineering Sciences 41 No.5, 1778-1795.

Viswanadham, B., Phanikumar, B., & Mukherjee, R. V. (2009). Swelling behavior of a geofiber-reinforced expansive soil. Geotechtile & Geomembranes , 27 No.1, 73-76.

Gueddouda, M. K., Goual, I., Lamara, M., Smaida, A., Mecarta, B. (2011). Chemical stabilization of expansive clays from Algeria. Global Journal of researches in engineering 11 No.5.

Al-Busoda, B. S., & Abbase, H. O. (2015). Mitigation of expansive soil problems by using helical piles with additives. J Geotech Eng, 2(2), 30-40.

Di Sante, M., Fratalocchi, E., Mazzieri, F., and Pasqualini, E. (2014). Time of reactions in a lime treated clayey soil and influence of curing conditions on its microstructure and behavior. Applied Clay Science 99, 100-109.

Bhuvaneshwari, S., Robinson, R. G., and Gandhi, S. R. (2014). Behavior of lime treated cured expansive soil composites. Indian Geotech. J., 44 No.3, 278–293.

Stoltz, G., Cuisinier, O. and, Masrouri, F. (2012) Multi-scale analysis of the swelling and shrinkage of lime treated expansive clayey soil. Applied Clay Science 61, 44-51.

Di Sante, M., Fratalocchi, E., Mazzieri, F., and Pasqualini, E. (2015). Influence of delayed compaction on the compressibility and hydraulic conductivity of soil-lime mixtures. Engineering Geology 185, 131-138.

Khattab, S. A., Al-Mukhtar, M., & Fleureau, J. M. (2007). Long-term stability characteristics of a lime-treated plastic soil. Journal of materials in civil engineering, 19(4), 358-366.

Nasrizar, A. A., Muttharam, M., and, Ilamparuthi, K. (2010). Role of Lime Content on Soil-Lime Reaction under Thermal Curing. Indian Geotechnical Conference – 2010, Geotrendz December 16–18, 2010 IGS Mumbai Chapter & IIT Bombay.

Boardman, D., I., Glendinning, S., ad Rogers, C., D., F., (2001) Development of stabilization and soil cation in lime-clay mixes. Geotechnique 50, No.6, 533-543.

Tran, T. D., Cui, Y., Tang, A. M., Audiguier, M., and Cojean, R. (2014). Effect of lime treatment on the microstructure and hydraulic conductivity of Hericourt clay. Journal of Rock Mechanics and Geotechnical Engineering 6, 399-404.

Nalbantoglu, Z., and Tuncer, E., R., (2001). Compressibility and hydraulic conductivity of a chemically treated expansive clay. Can. Geotech. J. 38, 154-160.

Khattab, S., Al-Juari, K., and Al-Kiki, I. (2008). Strength, durability and hydraulic properties of clayey soil stabilized with lime and industrial waste lime. Al-Rafidain Eng. J., 16 No.1, 102-116.

Al-Mukhtar, M., Leslegy, A., and Alcover, J. (2014) Lime consumption of different clayey soils. Applied Clay Science 95, 133-145.

Chindris, L., Radeanu, C., & Popa, C. (2017). Expansive Soil Stabilization-General Considerations. International Multidisciplinary Scientific GeoConference: SGEM, 17, 247-255.

Honghua, Z., Jun, L., Jing, G., Chunji, Z. and, Bi-wei, G (2014). Reexamination of lime stabilization mechanisms of expansive clay. Journal of Materials in Civil Engineering ASCE. 10, 1-34.

Sivapullaiah, P. V., Sridharan, A., and Raju, K. V. (2000). Role of amount and type of clay in the lime stabilization of soils. Ground Improvement, J. 4, 37-45.

Al-Mukhtar, M., Khattab, S, and Alcover, J. (2012). Microstructure and geotechnical properties of lime-treated expansive clayey soil. Engineering Geology 139-140, 17-27.

Galvao, T., C., D., Elsharief, A. and Simoes, G., F., (2004). Effect of lime on permeability and compressibility of two tropical residual soils. Journal of environmental Engineering ASCE 130. No. 8, 881-885.

Khattab, S. and Aldaood, M., (2009). Curing conditions effect on some engineering properties of lime treated expansive clay from Mosul area. Tikrit Eng. Tech. and science. J., 16 No.1, 1-15.

Jha, A. K., & Sivapullaiah, P. V. (2015). Mechanism of improvement in the strength and volume change behavior of lime stabilized soil. Engineering Geology, 198, 53-64.

Ali, H., & Mohamed, M. (2018). The effects of lime content and environmental temperature on the mechanical and hydraulic properties of extremely high plastic clays. Applied Clay Science, 161, 203-210.

Ontisuka, K., Modmoltin, C., and Kouno, M., (2001). Investigation on microstructure and strength of lime and cement stabilized Ariake clay. Saga University 30, No.1.

Yildiz, M. and, Soganci, A. S. (2012). Effect of freezing and thawing on strength and permeability of lime-stabilized clays. Scientia Iranica journal 19. No.4, 1013-1017.

Milburn, J.P. and R. Parsons, (2004). Performance of soil stabilization agents. Report KU-01-8, Kansas Department of Transportation, Topeka, KS.

Elsharief, A., Elhassan, A., and Mohamed, A., (2013). Lime stabilization of tropical soils from Sudan for road construction. Geotech. Constr. Mat. and Env. 4, No. 2, 533-538.

Khattab, S. and Aljboury, M., (2012). Effect of combined stabilization by lime and cement on hydraulic properties of clayey soil selected from Mosul area. Al-Rafidain Eng. J., 20 No.6, 139-153.

Published

2021-06-16

How to Cite

[1]
M. Awad, I. . Al-Kiki, and A. . Khalil, “Permeability of Expansive Soils Modified/Stabilized with lime (Review Paper)”, DJES, vol. 14, no. 2, pp. 129–140, Jun. 2021.

Issue

Diyala Journal of Engineering Sciences Vol.14, No 2, June 2021

Section

Original Articles
Copyright & Licensing

Copyright (c) 2021 Muwafaq Awad, Ibrahim Al-Kiki , Amina A Khalil

Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 International License.

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