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Forecasting the long-term deterioration of a cut slope in high-plasticity clay using a numerical model

Forecasting the long-term deterioration of a cut slope in high-plasticity clay using a numerical model
Forecasting the long-term deterioration of a cut slope in high-plasticity clay using a numerical model
This paper details development of a numerical modelling approach that has been
employed to forecast the long-term performance of a cut slope formed in high plasticity clay. It links hydrological and mechanical behaviour in a coupled saturated and unsaturated model. This is used to investigate the influence of combined dissipation of excavation-generated excess pore water pressures and seasonal weather-driven near-surface cyclic pore water pressures. Deterioration of slope performance is defined in terms of both slope deformations (i.e. service) and factor of safety against shear failure (i.e. safety). Uniquely, the modelling approach has been validated using 16 years of measured pore water pressure data from multiple locations in a London Clay cut slope. Slope deterioration was shown to be a function of both construction-induced pore water pressure dissipation and seasonal weather driven pore water pressure cycles. These lead to both transient and permanent changes in factor of safety due to effective stress variation and mobilisation of post-peak strength reduction over time, respectively, ultimately causing shallow first-time progressive failure. It is demonstrated that this long-term (90 year) deterioration in slope performance is governed by the hydrological processes in the weathered near surface soil zone that forms following slope excavation.
Clay Cut Slope, Deterioration, Forecasting, Numerical Modelling, Pore Water pressure, Seasonal Weather Cycles
0013-7952
Postill, Harry
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Helm, Peter R.
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Dixon, Neil
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Glendinning, Stephanie
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Smethurst, Joel
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Rouainia, Mohamed
6501a752-5283-4ceb-9aed-5b5ae31422c0
Briggs, Kevin M.
8974f7ce-2757-4481-9dbc-07510b416de4
El-Hamalawi, Ashraf
b289de62-636c-4651-8b82-62fc4e836742
Blake, Anthony
e0438bea-cfc4-4373-b100-8b9768ddc56f
Postill, Harry
38e98652-2fb6-4477-be05-38d0e6f0355a
Helm, Peter R.
1faf99e9-184c-4034-acc2-fad6114ea54e
Dixon, Neil
6272601b-f201-4828-898b-2b4b8d5e08c0
Glendinning, Stephanie
c0be9556-3210-4794-a36b-a483258a4b45
Smethurst, Joel
8f30880b-af07-4cc5-a0fe-a73f3dc30ab5
Rouainia, Mohamed
6501a752-5283-4ceb-9aed-5b5ae31422c0
Briggs, Kevin M.
8974f7ce-2757-4481-9dbc-07510b416de4
El-Hamalawi, Ashraf
b289de62-636c-4651-8b82-62fc4e836742
Blake, Anthony
e0438bea-cfc4-4373-b100-8b9768ddc56f

Postill, Harry, Helm, Peter R., Dixon, Neil, Glendinning, Stephanie, Smethurst, Joel, Rouainia, Mohamed, Briggs, Kevin M., El-Hamalawi, Ashraf and Blake, Anthony (2020) Forecasting the long-term deterioration of a cut slope in high-plasticity clay using a numerical model. Engineering Geology, [105912]. (doi:10.1016/j.enggeo.2020.105912).

Record type: Article

Abstract

This paper details development of a numerical modelling approach that has been
employed to forecast the long-term performance of a cut slope formed in high plasticity clay. It links hydrological and mechanical behaviour in a coupled saturated and unsaturated model. This is used to investigate the influence of combined dissipation of excavation-generated excess pore water pressures and seasonal weather-driven near-surface cyclic pore water pressures. Deterioration of slope performance is defined in terms of both slope deformations (i.e. service) and factor of safety against shear failure (i.e. safety). Uniquely, the modelling approach has been validated using 16 years of measured pore water pressure data from multiple locations in a London Clay cut slope. Slope deterioration was shown to be a function of both construction-induced pore water pressure dissipation and seasonal weather driven pore water pressure cycles. These lead to both transient and permanent changes in factor of safety due to effective stress variation and mobilisation of post-peak strength reduction over time, respectively, ultimately causing shallow first-time progressive failure. It is demonstrated that this long-term (90 year) deterioration in slope performance is governed by the hydrological processes in the weathered near surface soil zone that forms following slope excavation.

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Accepted/In Press date: 5 November 2020
Published date: 16 November 2020
Additional Information: Funding Information: The work presented is an output of the collaborative research project iSMART (grant number EP/K027050/1 ) and the programme grant ACHILLES (programme grant number EP/R034575/1 ) funded by the UK Engineering and Physical Sciences Research Council (EPSRC) . The instrumentation and earlier monitoring of the Newbury cutting site was funded by the UK EPSRC grant numbers GR/R72341/01 and EP/F063482/1 . The support of Highways England for access and maintenance activities at the Newbury site is also gratefully acknowledged. Publisher Copyright: © 2020 The Author(s)
Keywords: Clay Cut Slope, Deterioration, Forecasting, Numerical Modelling, Pore Water pressure, Seasonal Weather Cycles

Identifiers

Local EPrints ID: 445358
URI: http://eprints.soton.ac.uk/id/eprint/445358
ISSN: 0013-7952
PURE UUID: 1c543477-d81b-4c64-94f0-3c3fe3819d1a
ORCID for Joel Smethurst: ORCID iD orcid.org/0000-0001-8175-985X
ORCID for Kevin M. Briggs: ORCID iD orcid.org/0000-0003-1738-9692

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Date deposited: 03 Dec 2020 17:34
Last modified: 12 Aug 2024 01:36

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Contributors

Author: Harry Postill
Author: Peter R. Helm
Author: Neil Dixon
Author: Stephanie Glendinning
Author: Joel Smethurst ORCID iD
Author: Mohamed Rouainia
Author: Kevin M. Briggs ORCID iD
Author: Ashraf El-Hamalawi
Author: Anthony Blake

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