Modeling Rainfall‐Runoff and Soil Erosion Processes on Hillslopes With Complex Rill Network Planform

Wu, Songbai; Chen, Li; Wang, Ninglian; Yu, Mao-Hong; Assouline, S.

doi:10.1029/2018wr023837

Cited by 27 publications

(39 citation statements)

References 71 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…This is based on the consideration of soil surface sealing occurring during the first rainfall (Shen et al, 2015). The soil hydraulic properties of the two layers are quantified by Wu et al (2018). The soil saturated hydraulic conductivity of the top layer (1.0 cm in thickness), K 1s , decreases from 3.1 to 0.05 cm h −1 during the first rainfall and remained 0.05 cm h −1 for the second and third rainfalls, while the soil saturated hydraulic conductivity of the underlying layer soil, K 2s , remains at 3.1 cm h −1 .…”

Section: Water Resources Researchmentioning

confidence: 99%

“…The validation of simulated rill evolution includes the four key rill network characteristic parameters, that is, rill width, depth, orientation angle, and lateral density, as well as the runoff and erosion processes. Note that the approaches such as WEPP and Wu et al (2018) ignore the rill evolution processes, and thus, we only present the rill evolution results of the proposed model. Figures 3a-3c compare the measured lateral rill density to the simulated values, which are a function of the downslope distance, at the end of the three successive rainfalls.…”

Section: Hillslope Rill Evolutionmentioning

confidence: 99%

“…The accurate prediction of rill width and depth also validates the performance of the present modeling approach. Figure 4 shows the measured cumulative runoff depth and erosion compared with the simulated results by the present model, the model of Wu et al (2018), and the WEPP approach. The runoff depths simulated by the present model are very close to the observed values.…”

Section: 1029/2020wr027768mentioning

confidence: 99%

“…At the hillslope scale, soil erosion by overland flow usually generates complex rill networks (e.g., Berger et al, 2010; Bennett et al, 2015; Brunton & Bryan, 2000; Favis‐Mortlock, 1998; Favis‐Mortlock et al, 2000; Hofer et al, 2012; Moreno‐de las Heras et al, 2010). The characteristics of rill network vary remarkably with space and time and have great impacts on flow and sediment routing and soil erosion processes (Brunton & Bryan, 2000; Gumiere et al, 2009; Mancilla et al, 2005; Robichaud et al, 2010), which in turn affect the geomorphology of rill network (Oz et al, 2017; Shen et al, 2015; Wu et al, 2018). This means that soil erosion and rill evolution create a feedback loop where each part of the system responds to changes of other parts.…”

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Modeling Soil Erosion With Evolving Rills on Hillslopes

Chen

2020

Water Resources Research

Self Cite

View full text Add to dashboard Cite

Whereas current erosion models are successful in quantitative estimates of soil erosion by water flow, modeling the coevolution of geomorphological features, particularly rill network properties and soil erosion on hillslopes, is still a major challenge. In this study, we propose a rill evolution modeling approach and combine it with a rainfall-runoff and soil erosion model to simulate the feedback loop of hillslope geomorphic development and soil erosion processes. Rill evolution is mainly characterized by three rill network attributes, rill density, orientation angle, and rill width, all modeled with physical equations. The entire rainfall-runoff-erosion and rill evolution model is tested against a set of rill network evolution and soil erosion data from an experimental hillslope subjected to successive rainfall events. The simulated spatial and temporal variations of rill network characteristics and soil erosion agree well with the measured data. The results demonstrate that the three rill network characteristics continually alter the partitioning of interrill and rill flows and affect the interrill and rill flow erosivity and soil erosion, which in turn modify the rill geometry and rill network planform. Comparatively, existing approaches such as Water Erosion Prediction Project (WEPP) that ignore the rill evolution processes largely underestimate the hillslope soil erosion when using time independent model parameters. Moreover, a sensitivity analysis indicates that both the rill evolution and soil erosion processes are sensitive to the rill evolution parameters, rainfall intensity, and slope angle. These results can inform the development of general geomorphic evolution and soil erosion models on evolving rilled hillslopes.

show abstract

Section: Water Resources Researchmentioning

confidence: 99%

Section: Hillslope Rill Evolutionmentioning

confidence: 99%

Section: 1029/2020wr027768mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Modeling Soil Erosion With Evolving Rills on Hillslopes

Chen

2020

Water Resources Research

Self Cite

View full text Add to dashboard Cite

show abstract

“…This discrepancy likely occurred because we did not include the impacts of soil heterogeneities, vegetation, and rills in the present study, although they appear on many natural hillslopes. The soil heterogeneities can directly affect the soil infiltration and thus modified the run-off generation (Langhans et al, 2010(Langhans et al, , 2011, the vegetation may further complicate the results by directly enhancing the local infiltration rates and increasing the overland flow resistance (Chen et al, 2013(Chen et al, , 2016Moreno-de las Heras et al, 2010;Sidle, Hirano, Gomi, & Terajima, 2007), and the rills change the hillslope microtopography, overland flow routing, and function as flow conveyors (Nearing et al, 1997;Wu, Chen, Wang, Yu, & Assouline, 2018). Both of these factors can alter the rainfallrun-off mechanism and affect the scaling relationship, which warrant further investigations.…”

Section: Discussionmentioning

confidence: 99%

Variable power‐law scaling of hillslope Hortonian rainfall–runoff processes

Chen

Wang

et al. 2019

Hydrological Processes

Self Cite

View full text Add to dashboard Cite

Hydrological studies focused on Hortonian rainfall–run‐off scaling have found that the run‐off depth generally declines with the plot length in power‐law scaling. Both the power‐law proportional coefficient and the scaling exponent show great variability for specific conditions, but why and how they vary remain unclear. In the present study, the scaling of hillslope Hortonian rainfall–run‐off processes is investigated for different rainfall, soil infiltration, and hillslope surface characteristics using the physically based cell‐based rainfall‐infiltration‐run‐off model. The results show that both temporally intermittent and steady rainfalls can result in prominent power‐law scaling at the initial stage of run‐off generation. Then, the magnitude of the power‐law scaling decreases gradually due to the decreasing run‐on effect. The power‐law scaling is most sensitive to the rainfall and soil infiltration parameters. When the ratio of rainfall to infiltration exceeds a critical value, the magnitude of the power‐law scaling tends to decrease notably. For different intermittent rainfall patterns, the power‐law exponent varies in the range of −1.0 to −0.113, which shows an approximately logarithmic increasing trend for the proportional coefficient as a function of the run‐off coefficient. The scaling is also sensitive to the surface roughness, soil sealing, slope angle, and hillslope geometry because these factors control the run‐off routing and run‐on infiltration processes. These results provide insights into the variable scaling of the Hortonian rainfall–run‐off process, which are expected to benefit modelling of large‐scale hydrological and ecological processes.

show abstract

The effects of slope shape and polyacrylamide application on runoff, erosion and nutrient loss from hillslopes under simulated rainfall

Zeng

Yang

et al. 2021

Hydrological Processes

View full text Add to dashboard Cite

Natural hillslopes are mostly composed of complex slope shapes, which significantly affect soil erosion. However, existing studies have mainly focused on uniform slopes to simplify complex hillslopes, and the mechanisms responsible for the influence of slope shape on soil and nutrient losses are still not well understood, especially in the application of soil improvers to reduce soil loss. To investigate the effects of slope shape and polyacrylamide (PAM) application on runoff, soil erosion and nutrient loss, this study conducted artificial field rainfall experiments involving two PAM application rates and nine slope shapes. The results indicate that the average amount of soil loss from convex slopes was 1.5 and 1.3 times greater than that from concave and uniform slopes, respectively, and the average amount of ammonia nitrogen loss and phosphate loss increased by 24.0%-58.6%. Soil and nutrient losses increased as the convexity of the convex slopes increased. For runoff, there was little difference between concave and convex slopes, but the runoff amount for both slopes was greater than that for uniform slopes. After PAM application, the soil loss decreased by more than 90%, and the nutrient loss decreased by 28.2%-68.1%. The application of PAM was most effective in reducing soil erosion and nutrient loss from convex slopes, and it is recommended to appropriately increase the PAM application rate for convex slopes. A strong linear relationship between ammonia nitrogen and phosphate concentrations and sediment concentrations was found in the runoff on slopes with no PAM application. However, this linear relationship weakened for slopes with PAM application. The findings of this study may be valuable for optimizing nonpoint source pollution management in basins.

show abstract

Modeling Rainfall‐Runoff and Soil Erosion Processes on Hillslopes With Complex Rill Network Planform

Cited by 27 publications

References 71 publications

Modeling Soil Erosion With Evolving Rills on Hillslopes

Modeling Soil Erosion With Evolving Rills on Hillslopes

Variable power‐law scaling of hillslope Hortonian rainfall–runoff processes

The effects of slope shape and polyacrylamide application on runoff, erosion and nutrient loss from hillslopes under simulated rainfall

Contact Info

Product

Resources

About