Definition
Soils that have the potential to collapse generally possess porous textures with high void ratios and relatively low densities. At their natural moisture content these soils possess high apparent strength but they are susceptible to large reductions in void ratio on wetting, especially under load. In other words, the metastable texture collapses as the bonds between the grains break down as the soil becomes saturated (Culshaw et al. 2018).
Collapse of soils is controlled both microscopically and macroscopically, and both aspects need to be understood if the controls on collapse are to be determined. When collapse takes place, there is a rearrangement of soil particles resulting in densification. Collapse typically takes place rapidly as the soil passes from a metastable condition to a normally consolidated one.
Jefferson and Rogers (2012) defined collapsible soils as: “…soils in which the major structural units are initially arranged in a metastable packing through a suite...
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References
Assadi A (2014) Micromechanics of collapse in loess. Unpublished PhD thesis, University of Birmingham
Bell FG, Culshaw MG, Northmore KJ (2003) The metastability of some gull fill materials from Allington, Kent, UK. Q J Eng Geol Hydrogeol 36:217–229
Bell FG, Culshaw MG, Skinner HD (2012) Non-engineered fills. In: Burland J, Chapman T, Skinner H, Brown M (eds) ICE manual of geotechnical engineering, volume 1: geotechnical engineering principles, problematic soils and site investigation. ICE Publishing, London, pp 443–461
Culshaw MG, Northmore KJ, Jefferson I, Assadi A, Bell FG (2018) Collapsible soils in the UK. In: Giles DA (ed) Geological Hazards in the UK: their occurrence, monitoring and mitigation. Engineering geology special publication, vol 29. Geological Society, London, p xxx (in press)
Derbyshire E, Mellors TW (1988) Geological and geotechnical characteristics of some loess soils from China and Britain – a comparison. Eng Geol 25:135–175
Dibben SC (1998) A microstructure model for collapsing soils. Unpublished PhD thesis, Nottingham Trent University
El-Ruwaih IE, Tourma FT (1986) Assessment of the engineering properties of some collapsible soils in Saudi Arabia. In: Proceedings of the 5th international congress of the International Association of Engineering Geology, Buenos Aires, vol 2. A. A. Balkema, Rotterdam. pp 685–693
Fookes PG, Best R (1969) Consolidation characteristics of some late Pleistocene periglacial metastable soils of east Kent. Q J Eng Geol 2:103–128
Fort S (2017) Case history 1.4 – residential apartment blocks constructed on loess, Volgodonsk, Rostov Oblast, Russia. In: Griffiths JS, Martin CJ (eds) Engineering geology and geomorphology of glaciated and periglaciated terrains. Engineering geology special publication, vol 28. Geological Society, London, p 11
Gregersen O (1981) The quick clay landslide in Rissa, Norway. Norwegian geotechnical publication, vol 135, pp 1–6
Haskins DR, Bell FG, Schall A (1998) The evaluation of granite saprolite as a founding medium at Injaka Dam, Mpumalanga Province, South Africa. In: Moore DP, Hungr O (eds) Proceedings of the 8th congress of the International Association of Engineering Geology, Vancouver. A. A. Balkema, Rotterdam, 1, pp 461–468
Jefferson I, Rogers CDF (2012) Collapsible soils. In: Burland J, Chapman T, Skinner H, Brown M (eds) ICE manual of geotechnical engineering, volume 1: geotechnical engineering principles, problematic soils and site investigation. ICE Publishing, London, pp 391–411
Jefferson I, Tye C, Northmore KJ (2001) Behaviour of silt: the engineering characteristics of loess in the UK. In: Jefferson I, Murray EJ, Faragher E, Fleming PR (eds) Problematic soils, proceedings of the symposium held at The Nottingham Trent University. Thomas Telford Ltd, London, pp 37–52
Jefferson I, Rogers CDF, Evstatiev D, Karastanev D (2005) Treatment of metastable loess soils: lessons from Eastern Europe. In: Indraratna B, Chu J (eds) Ground improvement – case histories, Elsevier geo-engineering book series, vol 3. Elsevier, Amsterdam, pp 723–762
Lill GO (1976) The nature and distribution of loess in Britain. Unpublished PhD thesis, Department of Civil Engineering, University of Leeds
Northmore KJ, Culshaw MG, Hobbs PRN (1992) Engineering geology of tropical red clay soils: summary findings and their application for engineering purposes. Technical report WN/93/15. British Geological Survey, Keyworth/Nottingham
Northmore KJ, Bell FG, Culshaw MG (1996) The engineering properties and behaviour of the brickearth of south Essex. Q J Eng Geol 29:147–161
Northmore KJ, Jefferson I, Jackson PD, Entwisle DC, Milodowski AE, Raines MR, Gunn DA, Boardman DI, Zourmpakis A, Nelder LM, Rogers CDF, Dixon N, Smalley IJ (2008) On-site characterisation of loessic brickearth deposits at Ospringe, Kent, UK. Proceedings of the Institution of Civil Engineers, Geotechnical Engineering 161:3–17
Pereira JHF, Fredlund DG, Cardão Neto MP, De Gitirana GFN Jr (2005) Hydraulic behavior of collapsible compacted gneiss soil. J Geotech Geoenviron 131:1264–1273
Popescu ME (1992) Engineering problems associated with expansive and collapsible soil behaviour. In: Proceedings of the 7th international conference on expansive soils, vol 2, Dallas, pp 25–56
Rankka K, Andersson-Sköld Y, Hultén C, Larsson R, Leroux V, Dahlin T (2004) Quick clay in Sweden. Report no, 65. Swedish Geotechnical Institute, Linköping
Stumpf AJ (2013) Collapsing Soil Hazards. In: Bobrowsky PT (ed) Encyclopedia of Natural Hazards. Springer, pp 99–105
Waltham AC (2009) Foundations of engineering geology, 3rd edn. Hydraulic Behaviour/Taylor & Francis, Abingdon/Oxon
White JL, Greenman C (2008) Collapsible soils in Colorado, Engineering geology publication, vol 14. Colorado Geological Survey, Department of Natural Resources, Denver
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Culshaw, M., Jefferson, I. (2018). Collapsible Soils. In: Bobrowsky, P.T., Marker, B. (eds) Encyclopedia of Engineering Geology. Encyclopedia of Earth Sciences Series. Springer, Cham. https://doi.org/10.1007/978-3-319-73568-9_61
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