Abstract
Root growth alters soil fabric and consequently its mechanical and physical properties. Recent studies show that roots induce compaction of soil in their immediate vicinity, a region that is central for plant health. However, high quality quantification of root influence on the soil fabric, able to inform computational models is lacking from the literature. This study quantifies the relationship between soil physical characteristics and root growth, giving special emphasis on how roots in early stage formation influence the physical architecture of the surrounding soil structure. High-resolution X-ray micro-Computed Tomography (µCT) is used to acquire three dimensional images of two homogeneously-packed samples. It is observed that the void ratio profile extending from the soil-root interface into the bulk soil is altered by root growth. The roots considerably modify the immediate soil physical characteristics by creating micro cracks at the soil-root interface and by increasing void ratio. This paper presents the mechanisms that led to the observed structure as well as some of the implications that it has in such a dynamic zone.
Highlights
2 Materials and MethodsPlants are used as a natural solution against erosion and 2.1 Sample preparation shallow landslides
The idealised experiments in this paper provide validation case studies for future numerical simulations
The void ratio was quantified at four radii from the centroid of the root (i.e. 0.88mm, 1.42mm, 1.97mm and 10mm), representing both local and global void ratios, and was calculated as the number of voxels corresponding to voids over the number of voxels corresponding the solids
Summary
Plants are used as a natural solution against erosion and 2.1 Sample preparation shallow landslides. A better understanding of the soil structure can result in better growth and stabilisation of plants. Soil structure changes, such as particle organisation and increases in bulk density can strongly affect the growth and diameter of roots [6]. X-ray micro-computed tomography (μCT) was adopted to investigate the spatial distributions of voids and root volume ratios for the two samples, after 7 days of growth at room temperature. They reported that in some cases fine root grew into more dense area. This be- 2.2 Acquisition of X-ray computed tomography haviour is probably triggered by secondary factors, such images as water or nutrient availability. Figure 1. 3D reconstruction of the segmented root system of (a) the coarse glass beads sample with each type of root indicated (PR, primary root; LR1, lateral root 1; LR2, lateral root 2; LR3, lateral root 3; LR4, lateral root 4) and (b) the fine glass beads sample
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