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Prediction and experimental evaluation of soil-water retention behavior of skeletal calcareous soils

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Abstract

Skeletal calcareous soils refer to soils consisting of skeletal remains of marine organisms. Although calcareous deposits are prevalent along coastal plains throughout the world, there is no study which investigates their behavior in unsaturated conditions. In these conditions, soil-water retention capacity is a fundamental parameter in relation to many geotechnical, environmental, and agricultural aspects. Water retention capacity of a soil is expected to be influenced by intra-particle pores unique to calcareous soils. Scanning electron microscopy (SEM) and mercury intrusion porosimetry (MIP) used in the current study clearly revealed this special microstructural characteristic. To study water retention and hydraulic hysteresis behavior of skeletal calcareous soil (obtained from the Hormuz Island of Iran) compared with a reference silicate soil (obtained from the Netherlands), a series of tests were conducted using pressure plate and controlled-suction oedometer apparatuses. Test results showed that in similar grain-size distribution of these soils, water retention curves of calcareous and silica soils are almost the same in low suctions, but calcareous soil retains more water at higher suctions due to its intra-particle voids. In addition, owing to these microstructural pores, ratio of Sr reduction on wetting path of a hysteresis loop was found to be more for calcareous soil than for silicate soil. Besides, to find and/or modify a prediction method for water retention curve of calcareous soil with acceptable accuracy, several existing pedotransfer functions were evaluated. Results showed that models proposed by Zapata et al. (Geotech Spec Publ 99:84–124, 2000) and Saxton et al. (Soil Science Society of America Journal 50(4): 1031–1036, 1986) after some simple modifications provide accurate estimations for water retention curve of calcareous soils.

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References

  1. Arya LM, Paris JF (1981) A physicoempirical model to predict the soil moisture characteristic from particle-size distribution and bulk density data1. Soil Sci Soc Am J 45(6):1023–1030

  2. Aubertin M, Mbonimpa M, Bussière B, Chapuis R (2003) A model to predict the water retention curve from basic geotechnical properties. Can Geotech J 40(6):1104–1122

  3. Aung KK, Rahardjo H, Leong EC, Toll DGJG, Engineering G (2001) Relationship between porosimetry measurement and soil–water characteristic curve for an unsaturated residual soil. 19:401–416

  4. Augusto Filho, O., Fernandes, M. A. J. B. o. E. G., and Environment, 2018, Landslide analysis of unsaturated soil slopes based on rainfall and matric suction data. https://doi.org/10.1007/s10064-018-1392-5

  5. Birle E, Heyer D, Vogt N (2008) Influence of the initial water content and dry density on the soil–water retention curve and the shrinkage behavior of a compacted clay. Acta Geotech 3(3):191

  6. Bulut R, Leong EC (2008) Indirect measurement of suction, Laboratory and field testing of unsaturated soils. Springer, Berlin, pp 21–32

  7. Botula YD, Cornelis WM, Baert G, Van Ranst E (2012) Evaluation of pedotransfer functions for predicting water retention of soils in Lower Congo (D.R. Congo). Agric Water Manag 111:1–10

  8. Brandes H (2011) Simple shear behavior of calcareous and quartz sands. Geotech Geol Eng 29(1):113–126

  9. Brooks, R., and Corey, T., 1964, HYDRAU uc properties of porous media.

  10. Bumb AC, Murphy CL, Everett LG (1992) A comparison of three functional forms for representing soil moisture characteristics. Groundwater 30(2):177–185

  11. Burger CA, Shackelford CD (2001) Evaluating dual porosity of pelletized diatomaceous earth using bimodal soil-water characteristic curve functions. Can Geotech J 38(1):53–66

  12. Cataño J, Pando M (2010) Static and dynamic properties of a calcareous sand from Southwest PR, Advances in Analysis, Modeling, & Design, Proc. ASCE GeoFlorida, GeoFlorida

  13. Chiu CF, Yan WM, Yuen K-V (2012) Estimation of water retention curve of granular soils from particle-size distribution — a Bayesian probabilistic approach. Can Geotech J 49(9):1024–1035

  14. Coop M (1990) The mechanics of uncemented carbonate sands. Geotechnique 40(4):607–626

  15. Dehnavi Y, Shahnazari H, Salehzadeh H, Rezvani R (2010) Compressibility and undrained behavior of Hormuz calcareous sand. Electron J Geotech Eng 15:1684–1702

  16. Delage P, Romero E, Tarantino A (2008) Recent developments in the techniques of controlling and measuring suction in unsaturated soils, Unsaturated soils. In: Advances in geo-engineering. CRC Press, Florida, pp 49–68

  17. Diamond S (1970) Pore size distributions in clays. Clay Clay Miner 18:7–2

  18. Dolinar BJB o EG, Environment (2015) Prediction of the soil-water characteristic curve based on the specific surface area of fine-grained soils. 74(3):697–703

  19. Fredlund DG, Rahardjo H (1993) Soil mechanics for unsaturated soils. John Wiley & Sons, New Jersey

  20. Fredlund DG, Xing A (1994) Equations for the soil-water characteristic curve. Can Geotech J 31(4):521–532

  21. Fredlund MD, Wilson GW, Fredlund DG (2002) Use of the grain-size distribution for estimation of the soil-water characteristic curve. Can Geotech J 39(5):1103–1117

  22. Gao Y, Sun D a (2017) Soil-water retention behavior of compacted soil with different densities over a wide suction range and its prediction. Comput Geotech 91:17–26

  23. Gupta S, Larson W (1979) Estimating soil water retention characteristics from particle size distribution, organic matter percent, and bulk density. Water Resour Res 15(6):1633–1635

  24. Hassanlourad M, Salehzadeh H, Shahnazari H (2008) Dilation and particle breakage effects on the shear strength of calcareous sands based on energy aspects: Int. J Civ Eng 6(2):108–119

  25. Haverkamp R t, Parlange J-YJS s (1986) Predicting the water-retention curve from particle-size distribution: 1. Sandy soils without organic matter1 142(6):325–339

  26. Jafarian Y, Javdanian H, Haddad A (2018a) Dynamic properties of calcareous and siliceous sands under isotropic and anisotropic stress conditions. Soils Found 58:172–184

  27. Jafarian Y, Javdanian H, Haddad A (2018b) Strain-dependent dynamic properties of Bushehr siliceous-carbonate sand: experimental and comparative study. Soil Dyn Earthq Eng 107:339–349

  28. Johari A, Habibagahi G, Ghahramani A (2006) Prediction of soil–water characteristic curve using genetic programming. J Geotech Geoenviron 132(5):661–665

  29. Konrad J-M, Lebeau M (2015) Capillary-based effective stress formulation for predicting shear strength of unsaturated soils. Can Geotech J 52(12):2067–2076

  30. Laloui L (2013) Mechanics of unsaturated geomaterials. John Wiley & Sons, New Jersey

  31. Leij FJ, Russell WB, Lesch SM (1997) Closed-form expressions for water retention and conductivity data. Groundwater 35(5):848–858

  32. Lu N, Likos WJ (2004) Unsaturated soil mechanics. Wiley, New Jersey

  33. Marquardt DW (1963) An algorithm for least-squares estimation of nonlinear parameters. J Soc Ind Appl Math 11(2):431–441

  34. Murray EJ, Sivakumar V (2010) Unsaturated soils: a fundamental interpretation of soil behaviour. John Wiley & Sons, New Jersey

  35. Nicotera MV, Papa R, Gianfranco (2010) An experimental technique for determining the hydraulic properties of unsaturated pyroclastic soils. Geotech Test Jour Urciuoli 33(4):263–285

  36. Ng CW, Pang YJJ o g, engineering (2000) Influence of stress state on soil-water characteristics and slope stability. 126(2):157–166

  37. Ng CWW, Menzies B (2014) Advanced unsaturated soil mechanics and engineering. CRC Press, Florida

  38. Peron H, Hueckel T, Laloui L, Hu LB (2009) Fundamentals of desiccation cracking of fine-grained soils: experimental characterisation and mechanisms identification. Can Geotech J 46(10):1177–1201

  39. Peters A, W. (2008) Simplified evaporation method for determining soil hydraulic properties. J Hydro Durner 356(1-2):147–162

  40. Pham HQ, Fredlund DG, Barbour SL (2005) A study of hysteresis models for soil-water characteristic curves. Can Geotech J 42(6):1548–1568

  41. Pirone M, Papa R, Nicotera MV, Urciuoli G (2014) Evaluation of the Hydraulic Hysteresis of Unsaturated Pyroclastic Soils by in Situ Measurements. In: Procedia Earth and Planetary Science, vol 9, pp 163–170. https://doi.org/10.1016/j.proeps.2014.06.014

  42. Rashidian V, Hassanlourad M (2013) Application of an artificial neural network for modeling the mechanical behavior of carbonate soils. Intern Jour Geomech 14(1):142–150

  43. Rawles WJ, Brakensiek D (1982) Estimating soil water retention from soil properties. J Irrig Drain Div 108(2):166–171

  44. Rezvani R (2016) Post-cyclic volumetrci strain in saturated calcareous soil: Ph.D thesis. Iran University of Science and Technology (IUST), Tehran

  45. Rezvani R (2019) Shearing response of geotextile-reinforced calcareous soils using monotonic triaxial tests. In: Marine Georesources & Geotechnology, pp 1–12

  46. Ritter HL, Erich LC (1948) Pore size distribution in porous materials. Anal Chem 20:665–670

  47. Romero E, Gens A, Lloret A (2001) Temperature effects on the hydraulic behaviour of an unsaturated clay. In: Toll DG (ed) Unsaturated soil concepts and their application in geotechnical practice. Springer Netherlands, Dordrecht, pp 311–332

  48. Saha S, Gu F, Luo X, Lytton RL (2018) Prediction of soil-water characteristic curve for unbound material using Fredlund–Xing equation-based ANN approach. J Mater Civ Eng 30(5):06018002

  49. Salager S, Nuth M, Ferrari A, Laloui L (2013) Investigation into water retention behaviour of deformable soils. Can Geotech J 50(2):200–208

  50. Saxton K, Rawls WJ, Romberger J, Papendick R (1986) Estimating generalized soil-water characteristics from texture 1. Soil Sci Soc Am J 50(4):1031–1036

  51. Scheinost AC, Sinowski W, Auerswald K (1997) Regionalization of soil water retention curves in a highly variable soilscape, I. Developing a new pedotransfer function. Geoder 78(3):129–143

  52. Shahnazari H, Jafarian Y, Tutunchian MA, Rezvani R (2016) Undrained cyclic and monotonic behavior of Hormuz calcareous sand using hollow cylinder simple shear tests. Intern Jour Civ Engin:1–11

  53. Shahnazari H, Rezvani R, Tutunchian MA (2017) Experimental study on the phase transformation point of crushable and noncrushable soils. Mar Georesour Geotechnol 35(2):176–185

  54. Sharma SS, Ismail MA (2006) Monotonic and cyclic behavior of two calcareous soils of different origins. J Geotech Geoenviron 132:1581–1591

  55. Sreedeep S, Singh DN (2006) Methodology for determination of osmotic suction of soils. Geotech Geol Eng 24(5):1469–1479

  56. Sun P, Wang G, Wu LZ, Igwe O, Zhu EJB o EG, Environment (2018) Physical model experiments for shallow failure in rainfall-triggered loess slope. China, Northwest

  57. Tao H, Chen C, Jiang P, Tang L (2017) Soil water characteristic curves based on particle analysis. Proced engin 174:1289–1295

  58. Tarantino AJG (2009) A water retention model for deformable soils. 59:751–762

  59. Thyagaraj T, Rao SM (2010) Influence of osmotic suction on the soil-water characteristic curves of compacted expansive clay. J Geotech Geoenviron 136(12):1695–1702

  60. Tomasella J, Hodnett MG (1998) Estimating soil water retention characteristics from limited data in Brazilian Amazonia. Soil Sci 163(3):190–202

  61. Uchaipichat A, Khalili N (2009) Experimental investigation of thermo-hydro-mechanical behaviour of an unsaturated silt. Géotechnique 59(4):339–353

  62. Van Genuchten MT (1980) A closed-form equation for predicting the hydraulic conductivity of unsaturated soils 1. Soil Sci Soc Am J 44(5):892–898

  63. Vanapalli SK, Fredlund DG, Pufahl DE (1999) The influence of soil structure and stress history on the soil–water characteristics of a compacted till. Géotechnique 49(2):143–159

  64. Vereecken H, Maes J, Feyen J, DARIUS P (1989) Estimating the soil moisture retention characteristic from texture, bulk density, and carbon content. Soil Sci 148(6):389–403

  65. Wang JP, Hu N, François B, Lambert P (2017) Estimating water retention curves and strength properties of unsaturated sandy soils from basic soil gradation parameters. Water Resour Res 53(7):6069–6088

  66. Wang L, Huang C, Huang L (2018) Parameter estimation of the soil water retention curve model with Jaya algorithm. Comput Electron Agric 151:349–353

  67. Wassar F, Gandolfi C, Rienzner M, Chiaradia EA, Bernardoni E (2016) Predicted and measured soil retention curve parameters in Lombardy region north of Italy. Internl Soil and Water Conserv Res 4(3):207–214

  68. Williams J, Prebble R, Williams W, Hignett CJSR (1983) The influence of texture, structure and clay mineralogy on the soil moisture characteristic. 21(1):15–32

  69. Yang S, Shen X, Liu H, Ge H, Rui X (2019) Gradation affects basic mechanical characteristics of Chinese calcareous sand as airport subgrade of reefs. Mar Georesour Geotechnol:1–10

  70. Zapata CE, Houston WN, Houston SL, Walsh KD (2000) Soil-water characteristic curve variability. Geotech Spec Publ 99:84–124

  71. Zhou A-N, Sheng D, Li J (2014) Modelling water retention and volume change behaviours of unsaturated soils in non-isothermal conditions. Comput Geotech 55:1–13

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Acknowledgments

All tests in this research were performed in the Laboratory of Soil Mechanics (LMS) at École Polytechnique Fédéale de Lausanne (EPFL) in Switzerland. The technical supports are thankfully acknowledged. The helpful discussions with Prof. Alessio Ferrari are highly appreciated.

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Correspondence to H. Shahnazari.

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Shahnazari, H., Laloui, L., Kouzegaran, S. et al. Prediction and experimental evaluation of soil-water retention behavior of skeletal calcareous soils. Bull Eng Geol Environ (2020). https://doi.org/10.1007/s10064-019-01695-9

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Keywords

  • Skeletal calcareous soil
  • SWRC
  • Hydraulic hysteresis
  • Pedotransfer functions
  • Pressure plate extractor
  • Controlled-suction oedometer