Soil penetration by earthworms and plant roots — mechanical energetics of bioturbation of compacted soils
Soil penetration by earthworms and plant roots — mechanical energetics of bioturbation of compacted soils
We quantify mechanical processes common to soil penetration by earthworms and growing plant roots, including the energetic requirements for soil plastic displacement. The basic mechanical model considers cavity expansion into a plastic wet soil involving wedging by root tips or earthworms via cone-like penetration followed by cavity expansion due to pressurized earthworm hydroskeleton or root radial growth. The mechanical stresses and resulting soil strains determine the mechanical energy required for bioturbation under different soil hydro-mechanical conditions for a realistic range of root/earthworm geometries. Modeling results suggest that higher soil water content and reduced clay content reduce the strain energy required for soil penetration. The critical earthworm or root pressure increases with increased diameter of root or earthworm, however, results are insensitive to the cone apex (shape of the tip). The invested mechanical energy per unit length increase with increasing earthworm and plant root diameters, whereas mechanical energy per unit of displaced soil volume decreases with larger diameters. The study provides a quantitative framework for estimating energy requirements for soil penetration work done by earthworms and plant roots, and delineates intrinsic and external mechanical limits for bioturbation processes. Estimated energy requirements for earthworm biopore networks are linked to consumption of soil organic matter and suggest that earthworm populations are likely to consume a significant fraction of ecosystem net primary production to sustain their subterranean activities.
Ruiz, Siul
d79b3b82-7c0d-47cc-9616-11d29e6a41bd
Or, Dani
a0259fc3-35b3-4d5d-9540-867daf06473a
Schymanski, Stanislaus J.
88be1c59-47d9-4c2d-922b-bfe0939901ec
18 June 2015
Ruiz, Siul
d79b3b82-7c0d-47cc-9616-11d29e6a41bd
Or, Dani
a0259fc3-35b3-4d5d-9540-867daf06473a
Schymanski, Stanislaus J.
88be1c59-47d9-4c2d-922b-bfe0939901ec
Ruiz, Siul, Or, Dani and Schymanski, Stanislaus J.
(2015)
Soil penetration by earthworms and plant roots — mechanical energetics of bioturbation of compacted soils.
PLoS ONE, 10 (6), [e0128914].
(doi:10.1371/journal.pone.0128914).
Abstract
We quantify mechanical processes common to soil penetration by earthworms and growing plant roots, including the energetic requirements for soil plastic displacement. The basic mechanical model considers cavity expansion into a plastic wet soil involving wedging by root tips or earthworms via cone-like penetration followed by cavity expansion due to pressurized earthworm hydroskeleton or root radial growth. The mechanical stresses and resulting soil strains determine the mechanical energy required for bioturbation under different soil hydro-mechanical conditions for a realistic range of root/earthworm geometries. Modeling results suggest that higher soil water content and reduced clay content reduce the strain energy required for soil penetration. The critical earthworm or root pressure increases with increased diameter of root or earthworm, however, results are insensitive to the cone apex (shape of the tip). The invested mechanical energy per unit length increase with increasing earthworm and plant root diameters, whereas mechanical energy per unit of displaced soil volume decreases with larger diameters. The study provides a quantitative framework for estimating energy requirements for soil penetration work done by earthworms and plant roots, and delineates intrinsic and external mechanical limits for bioturbation processes. Estimated energy requirements for earthworm biopore networks are linked to consumption of soil organic matter and suggest that earthworm populations are likely to consume a significant fraction of ecosystem net primary production to sustain their subterranean activities.
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journal.pone.0128914
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Published date: 18 June 2015
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Local EPrints ID: 434285
URI: http://eprints.soton.ac.uk/id/eprint/434285
ISSN: 1932-6203
PURE UUID: 530c90a9-da32-458c-ac68-bdb63a37d489
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Date deposited: 18 Sep 2019 16:30
Last modified: 16 Mar 2024 04:07
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Author:
Dani Or
Author:
Stanislaus J. Schymanski
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