DRAM: a three-dimensional analytical model for the mobilisation of root reinforcement in direct shear conditions
DRAM: a three-dimensional analytical model for the mobilisation of root reinforcement in direct shear conditions
Roots can stabilise slopes against shallow landslides by mobilising their mechanical strength. Existing analytical models are highly simplified and typically focus on the ultimate limit state only, thus providing little insight into the underlying mechanism of reinforcement mobilisation. A new analytical model (‘DRAM’) was therefore developed to predict mechanical root reinforcement as a function of direct shear displacements. This model accounts for elasto-plastic root behaviour, three-dimensional root orientations, root failure through breakage or slippage, and a dynamically changing shear zone thickness. Comparison to two independent experimental direct shear data sets showed that the model was able to accurately predict the gradual mobilisation of root strength, the magnitude of peak root reinforcement, as well as the presence of significant root reinforcement at large shear displacements, associated with a relatively large quantity of roots slipping out of the surrounding soil. Because the newly developed model more closely resembles the underlying physics of the mobilisation of root reinforcement in direct shear while still being easy to use, it will be a useful tool for the engineering industry, in terms of quantifying root reinforcement distribution for limit analyses at the ultimate limit state, as well as for directing future research into the drivers of mechanical root reinforcement.
Analytical modelling, Direct shear, Landslides, Root reinforcement, Vegetation
106621
Meijer, G.j.
7b9009ee-fc42-434b-82ab-827cf7959e79
Knappett, J.A.
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Bengough, A.g.
ac1f754e-002c-44f6-8907-8771a4cd1fd3
Bull, D.j.
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Liang, T.
2cb6fdc4-f5c7-4b1a-8012-0bdc33cb037f
Muir Wood, D.
bf2e40d1-1c8b-43b8-87d6-f18af8f34a01
1 June 2022
Meijer, G.j.
7b9009ee-fc42-434b-82ab-827cf7959e79
Knappett, J.A.
cda30027-553d-4310-8a05-e48d8989a545
Bengough, A.g.
ac1f754e-002c-44f6-8907-8771a4cd1fd3
Bull, D.j.
3569ba02-89de-4398-a14d-02c3f9b4eab2
Liang, T.
2cb6fdc4-f5c7-4b1a-8012-0bdc33cb037f
Muir Wood, D.
bf2e40d1-1c8b-43b8-87d6-f18af8f34a01
Meijer, G.j., Knappett, J.A., Bengough, A.g., Bull, D.j., Liang, T. and Muir Wood, D.
(2022)
DRAM: a three-dimensional analytical model for the mobilisation of root reinforcement in direct shear conditions.
Ecological Engineering, 179, , [106621].
(doi:10.1016/j.ecoleng.2022.106621).
Abstract
Roots can stabilise slopes against shallow landslides by mobilising their mechanical strength. Existing analytical models are highly simplified and typically focus on the ultimate limit state only, thus providing little insight into the underlying mechanism of reinforcement mobilisation. A new analytical model (‘DRAM’) was therefore developed to predict mechanical root reinforcement as a function of direct shear displacements. This model accounts for elasto-plastic root behaviour, three-dimensional root orientations, root failure through breakage or slippage, and a dynamically changing shear zone thickness. Comparison to two independent experimental direct shear data sets showed that the model was able to accurately predict the gradual mobilisation of root strength, the magnitude of peak root reinforcement, as well as the presence of significant root reinforcement at large shear displacements, associated with a relatively large quantity of roots slipping out of the surrounding soil. Because the newly developed model more closely resembles the underlying physics of the mobilisation of root reinforcement in direct shear while still being easy to use, it will be a useful tool for the engineering industry, in terms of quantifying root reinforcement distribution for limit analyses at the ultimate limit state, as well as for directing future research into the drivers of mechanical root reinforcement.
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Accepted/In Press date: 15 March 2022
Published date: 1 June 2022
Additional Information:
Funding Information:
This research was funded by EPSRC grant EP/M020355/1 , which is a collaboration between the University of Dundee, the University of Southampton, the University of Aberdeen, Durham University and The James Hutton Institute. μVIS X-ray imaging work was supported by EPSRC grant EP/H01506X . The James Hutton Institute receives funding from the Scottish Government (Rural & Environmental Services & Analytical Services Division).
Publisher Copyright:
© 2022
Keywords:
Analytical modelling, Direct shear, Landslides, Root reinforcement, Vegetation
Identifiers
Local EPrints ID: 457946
URI: http://eprints.soton.ac.uk/id/eprint/457946
ISSN: 0925-8574
PURE UUID: 5596a91a-c814-494f-bcd0-46ece9222ff0
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Date deposited: 23 Jun 2022 17:07
Last modified: 16 Mar 2024 17:48
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Contributors
Author:
G.j. Meijer
Author:
J.A. Knappett
Author:
A.g. Bengough
Author:
T. Liang
Author:
D. Muir Wood
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