Kenneth Loades scite author profile

Background Plants alter their environment in a number of ways. With correct management, plant communities can positively impact soil degradation processes such as surface erosion and shallow landslides. However, there are major gaps in our understanding of physical and ecological processes on hillslopes, and the application of research to restoration and engineering projects.Scope To identify the key issues of concern to researchers and practitioners involved in designing and implementing projects to mitigate hillslope instability, we organized a discussion during the From this discussion, ten key issues were identified, considered as the kernel of future studies concerning the impact of vegetation on slope stability and erosion processes. Each issue is described and a discussion at the end of this paper addresses how we can augment the use of ecological engineering techniques for mitigating slope instability. Conclusions We show that through fundamental and applied research in related fields (e.g., soil formation and biogeochemistry, hydrology and microbial ecology), reliable data can be obtained for use by practitioners seeking adapted solutions for a given site. Through fieldwork, accessible databases, modelling and collaborative projects, awareness and acceptance of the use of plant material in slope restoration projects should increase significantly, particularly in the civil and geotechnical communities.

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Root anatomical phenes predict root penetration ability and biomechanical properties in maize (Zea Mays)

Chimungu

2015

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Planting density influence on fibrous root reinforcement of soils

Loades

Bengough²,

Bransby

et al. 2010

Ecological Engineering

176

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Root hairs aid soil penetration by anchoring the root surface to pore walls

Bengough

Loades

McKenzie

2016

EXBOTJ

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Root anatomical traits contribute to deeper rooting of maize under compacted field conditions

Vanhees

Loades

Bengough

et al. 2020

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Abstract To better understand the role of root anatomy in regulating plant adaptation to soil mechanical impedance, 12 maize lines were evaluated in two soils with and without compaction treatments under field conditions. Penetrometer resistance was 1–2 MPa greater in the surface 30 cm of the compacted plots at a water content of 17–20% (v/v). Root thickening in response to compaction varied among genotypes and was negatively associated with rooting depth at one field site under non-compacted plots. Thickening was not associated with rooting depth on compacted plots. Genotypic variation in root anatomy was related to rooting depth. Deeper-rooting plants were associated with reduced cortical cell file number in combination with greater mid cortical cell area for node 3 roots. For node 4, roots with increased aerenchyma were deeper roots. A greater influence of anatomy on rooting depth was observed for the thinner root classes. We found no evidence that root thickening is related to deeper rooting in compacted soil; however, anatomical traits are important, especially for thinner root classes.

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Kenneth Loades

Ecological mitigation of hillslope instability: ten key issues facing researchers and practitioners

Root anatomical phenes predict root penetration ability and biomechanical properties in maize (Zea Mays)

Planting density influence on fibrous root reinforcement of soils

Root hairs aid soil penetration by anchoring the root surface to pore walls

Root anatomical traits contribute to deeper rooting of maize under compacted field conditions

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