Rill erosion on an oxisol influenced by a thin compacted layer

Thomaz, Edivaldo Lopes

doi:10.1590/s0100-06832013000500027

Cited by 6 publications

(6 citation statements)

References 25 publications

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“…Firstly, when the soil becomes saturated, the soil surface runoff is also altered due to reduced soil infiltration capability under the saturation status compared with that under non‐saturated soil (Defersha, Quraishi, & Melesse, 2011; Zegeye et al, 2010; Zegeye et al, 2016). Then, a large flow velocity over the saturated soil slope can transport more sediments than that over the non‐saturated soil slope, as previously discussed (Gabbard, Huang, Norton, & Steinhardt, 1998; Lin, Brooks, McDaniel, & Boll, 2008; Thomaz, 2013). Soil erosion over saturated soil slopes usually produces a relatively smooth rill bed without abrupt headcuts (Y. H. Huang et al, 2018), decreasing the energy consumption of water flow, and results in the transportation of additional sediments.…”

Section: Discussionmentioning

confidence: 60%

“…However, the STC value of the saturated loess slope was approximately 25% larger than that of the non‐saturated soil slope (Figure 7). This finding indicates that a saturated loess slope could transport more sediments than a non‐saturated one (Rockwell, 2002; Thomaz, 2013; Wilson et al, 2007), and the occurrence of rill erosion on a saturated loess slope is possible.…”

Section: Discussionmentioning

confidence: 96%

“…Thus, the hydrodynamics on saturated slopes is significantly altered compared with that on non‐saturated soil slopes. Therefore, additional sediments could be transported under the same slope gradient and unit‐width flow rate (Rockwell, 2002; Thomaz, 2013; Wilson et al, 2007). Meanwhile, the occurrence of headcuts over saturated soil slopes is unlikely during the erosion process, thus avoiding waterfalls that slow down flow velocity and kinetic energy (Y. H. Huang et al, 2018).…”

Section: Discussionmentioning

confidence: 99%

“…The saturated condition may change the boundary layer status of the rill bed and reduce its frictional resistance (Zhang et al, 2017). All these factors resulted in an easily erodible soil and a larger STC over the saturated soil slope than over the non‐saturated one under the same slope gradient and unit‐width flow rate (Rockwell, 2002; Thomaz, 2013; Wilson et al, 2007).…”

Section: Discussionmentioning

confidence: 99%

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Experimental determination of sediment transport capacity of concentrated water flow over saturated soil slope

Huang

Liu

et al. 2020

European J Soil Science

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Sediment transport capacity (STC) is an important variable for characterising soil erosion on hillslopes. STC also determines the capability of sediment delivery and solute transportation. An experimental methodological strategy was developed in this study to measure the STC in eroding rills on a saturated soil slope. The STC was ensured by using a slope‐raised flume section to feed sufficient amounts of sediments into the water flow, and a flume section was used to stabilize the water flow and produce sediment concentration at the STC level for measurement. Experiments under four slope gradients of 5°, 10°, 15° and 20° and three unit‐width flow rates of 0.33, 0.67 and 1.33 × 10−3 m3 s−1 m−1 were conducted to measure the STCs on saturated soil slopes, with the experiments on STCs on non‐saturated soil slopes as control treatments. The measured STCs range from 0.16 to 1.41 kg s−1 m−1 over the saturated loess slopes. The STC measurement method for saturated soil slopes was verified as feasible by the small SDs of the measured STCs and the agreement between the trend of rill sediment delivery rate and the STC values at the slope gradient of 20° and three unit‐width discharges. The relationships between STC and slope gradient and those between STC and unit‐width flow rate over saturated soil slopes matched well with the power and linear functions, respectively. Furthermore, the STC values correlated well with the flow velocity. The STC value on the saturated loess slope was approximately 25% larger than that on the non‐saturated loess slope. An empirical power function of slope gradient and unit‐width flow rate was found to predict the STC on saturated loess slopes effectively. Therefore, the measurement method for soil erosion from saturated soil slopes can help to estimate the STC and obtain key parameters for the soil erosion prediction model. Highlights The sediment feeding by slope‐raised flume section was used to measure sediment transport capacity (STC) of saturated soil slope, and its feasibility was tested. The STC value over the saturated soil slope was significantly greater than that over non‐saturated soil slope. The STC over the saturated soil slope could be empirically expressed as the product of power functions of water flow rate and slope gradient.

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Section: Discussionmentioning

confidence: 60%

Section: Discussionmentioning

confidence: 96%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

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Experimental determination of sediment transport capacity of concentrated water flow over saturated soil slope

Huang

Liu

et al. 2020

European J Soil Science

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“…However, rill erosion processes on the roadbed differ substantially from rill erosion on agricultural lands (Foltz et al , ). Therefore, our common understanding of the importance of rills on surface erosion might not be applicable to our experiments on roads where a highly compacted layer prevents rill deepening and avoids sediment detachment (Thomaz, ). Rainfall rates during our simulation experiments were not sufficient to expand the existing rill network; thus, erosion from our micro‐catchments represents the integration of interill erosion and sediment transport through the rill network.…”

Section: Discussionmentioning

confidence: 99%

Rill length and plot‐scale effects on the hydrogeomorphologic response of gravelly roadbeds

Thomaz

Ramos‐Scharrón

2015

Earth Surf Processes Landf

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Although unpaved roads are well‐recognized as important sources of Hortonian overland flow and sediment in forested areas, their role in agriculturally‐active rural settings still lacks adequate documentation. In this study, we assessed the effect of micro‐catchment size, slope, and ground cover on runoff and sediment generation from graveled roadbeds servicing a rural area in southern Brazil. Fifteen replications based on 30‐min‐long simulated rainfall experiments were performed at constant rainfall intensities of 22–58 mm h−1 on roadbeds with varying characteristics including ~3–7 m2 micro‐catchment areas, 2–11° slopes, 2–9.7‐m‐long shallow rill features, and 30–100% gravel cover. The contributions of micro‐catchment size and rill length were the most important physical characteristics affecting runoff response and sediment production; both the size of the micro‐catchment and the length of the rills were inversely related to sediment loss and this contradicts most of the rill erosion literature. The effect of micro‐catchment size on runoff and sediment response suggests a potentially problematic spatial‐scale subjectivity of experimental plot results. The inverse relationship between rill length and sediment generation is interpreted here as related to the predominance of coarse fragments within rills, the inability of the shallow flows generated during the simulations to erode this sediment, and their role as zones of net sediment storage. Copyright © 2015 John Wiley & Sons, Ltd.

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Irrigation runoff from a rolling landscape with slowly permeable subsoils in New Zealand

Laurenson

Cichota

Reese³

et al. 2018

Irrig Sci

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Rill erosion on an oxisol influenced by a thin compacted layer

Cited by 6 publications

References 25 publications

Experimental determination of sediment transport capacity of concentrated water flow over saturated soil slope

Experimental determination of sediment transport capacity of concentrated water flow over saturated soil slope

Rill length and plot‐scale effects on the hydrogeomorphologic response of gravelly roadbeds

Irrigation runoff from a rolling landscape with slowly permeable subsoils in New Zealand

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