Effects of weeding the shrub layer during thinning on surface soil erosion in a hinoki plantation

Soil erosion potential maps and summary statistics can be produced from existing information with relative ease with the aid of computers. Soil maps are digitized and survey information is stored as attributes for each soil. Algorithms are then prepared which evaluate the appropriate data base attributes (e.g. texture, slope) for each interpretation. Forty surface soil erosion potential maps were produced for the Lower Fraser Valley which identify the most erosion-prone areas and indicate average potential soil losses to be expected under assumed conditions. The algorithm developed follows the universal soil loss equation. Differences across the landscape in the R, K, and S factors are taken into account whereas the L factor is considered as a constant equal to 1.0. Worst conditions of bare soil (no crop cover, i.e. C = 1.0) and no erosion control practices (i.e. P = 1.0) are assumed. The five surface soil erosion potential classes are determined by a weighted average annual soil loss value based both on the upper 20 cm of mineral soil and on the proportion of the various soils in the polygon. A unique polygon number shown on the erosion potential map provides a link to computer tables which give additional information for each individual soil within that polygon. Key words: Erosion, computer mapping, USLE

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Study on Surface Soil Erosion of Bhogdoi River Basin Using GIS and Remote Sensing

Lecture Notes in Civil Engineering - Proceedings of the Indian Geotechnical Conference 2019 ◽

10.1007/978-981-33-6370-0_62 ◽

2021 ◽

pp. 715-726

Author(s):

Merina Englengpi ◽

M. K. Dutta

Keyword(s):

Remote Sensing ◽

Soil Erosion ◽

River Basin ◽

Surface Soil ◽

Gis And Remote Sensing

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An assessment of soil loss and natural hazards in Nepal

Journal of Nepal Geological Society ◽

10.3126/jngs.v21i0.32150 ◽

2000 ◽

Vol 21 ◽

Author(s):

Dinesh R. Shiwakoti

Keyword(s):

Soil Erosion ◽

Debris Flow ◽

Soil Loss ◽

Surface Soil ◽

Mass Movements ◽

Critical Factors ◽

Outburst Flood ◽

Paper Briefly ◽

Grass Roots ◽

The Status

This paper briefly reviews the status of soil erosion in Nepal, and examines the major causes and factors leading to soil erosion and mass movements. There are the following four major mechanisms associated with soil loss: a) surface soil erosion, b) landslide and debris flow, c) earthquake, and d) glacier lake outburst flood. Effective methods for investigating, analysing, identifying, and implementing the critical factors for protecting accelerated soil loss in a planned manner are essential from the grass roots to national and international levels.

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Development of Web GIS based Surface Soil Erosion Prediction System

10.5194/egusphere-egu2020-12909 ◽

2020 ◽

Author(s):

Dongjun Lee ◽

Jae E Yang ◽

Kyoung Jae Lim ◽

Jonggun Kim ◽

Won Seok Jang

Keyword(s):

Soil Erosion ◽

Best Management Practices ◽

Management Practices ◽

Surface Soil ◽

Web Gis ◽

Analysis Tool ◽

Prediction System ◽

Erosion Prediction ◽

Soil Information ◽

The Web

<p>This study is to develop the Web GIS-based surface soil erosion prediction system that informs soil information such as daily potential soil erosion, soil quality, and best management practices (BMPs). The system involves three functions that are: 1) to predict daily potential soil erosion in the study areas (e.g., Jaun-Cheon, Bukhan-Gang, Namhan-Gang, and Gyoungan-Cheon); 2) to provide the current levels of soil qualities at field scale; 3) to recommend BMPs which can improve soil qualities. This study developed a module based on MUSLE and assessed the availability of the module comparing with the measured data at sample fields (3%, 9% slope). After verification of the module, the Web GIS-based system was developed using a user-friendly interface. The users can obtain the visualized soil erosion information through the interface and compare the amount of soil erosion using the single field or multi-fields analysis tool developed in this study. Moreover, the users can find the current level of soil qualities at fields they selected and gain various applicable BMPs information. The system enables to inform non-experts to soil information without using a complex model and equation. Therefore, the system can play a significant role in recognizing the importance of soil resources and enacting laws relative to soil conservation.</p>

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The relationship of soil organic carbon to 210Pbex and 137Cs during surface soil erosion in a hillslope forested environment

Geoderma ◽

10.1016/j.geoderma.2012.08.030 ◽

2013 ◽

Vol 192 ◽

pp. 59-67 ◽

Cited By ~ 24

Author(s):

Mengistu T. Teramage ◽

Yuichi Onda ◽

Hiroaki Kato ◽

Yoshifumi Wakiyama ◽

Shigeru Mizugaki ◽

...

Keyword(s):

Soil Erosion ◽

Organic Carbon ◽

Soil Organic Carbon ◽

Surface Soil ◽

Relationship Of ◽

The Relationship

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New molecular evidence for surface and sub-surface soil erosion controls on the composition of stream DOM during storm events

10.5194/bg-2017-252 ◽

2017 ◽

Cited By ~ 1

Author(s):

Marie Denis ◽

Laurent Jeanneau ◽

Patrice Petitjean ◽

Anaëlle Murzeau ◽

Marine Liotaud ◽

...

Keyword(s):

Organic Matter ◽

Soil Erosion ◽

Soil Solution ◽

Surface Runoff ◽

Surface Soil ◽

Molecular Evidence ◽

Storm Events ◽

Soil Solutions ◽

Chemical Segregation ◽

Dom Composition

Abstract. Storm events are responsible for more than 60 % of the export of dissolved organic matter (DOM) from headwater catchments due to an increase in both the discharge and concentration. The latter was attributed to changing water pathways inducing the mobilization of DOM from the surface soil horizons. Recent molecular investigations have challenged this view and hypothesized (i) a contribution of an in-stream partition of organic matter (OM) between eroded particles and the dissolved fraction and (ii) the modification of the composition of soil DOM during storm events. To investigate these assumptions, soil solutions in the macropores, surface runoff and stream outlet were sampled at high frequency during three storm events in the Kervidy-Naizin catchment, part of the French critical zone observatory AgrHys. The molecular composition of the DOM was analysed by thermally assisted hydrolysis and methylation (THM) with tetramethylammonium hydroxide (TMAH) coupled to a gas chromatograph and a quadrupole mass spectrometer. These analyses highlighted a modification of the DOM composition in soil solution controlled by the water-table dynamic and pre-event hydrological conditions. These findings fits with the mechanism of colloidal and particulate destabilization in the soil macroporosity. The different behaviour observed for lignins, carbohydrates and fatty acids highlights a potential chemical segregation based on their hydrophobicity. The composition of surface runoff DOM is similar to the DOM composition in soil solution and could be generated by the same mechanism. The DOM composition in both soil solution and surface runoff corresponds to the stream DOM composition observed during storm events. On the basis of these results, modifications of the stream DOM composition during storm events seem to be due to surface and sub-surface soil erosion rather than in-stream production.

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Influence of infiltration on soil erosion in green infrastructures

Acta Horticulturae et Regiotecturae ◽

10.2478/ahr-2021-0018 ◽

2021 ◽

Vol 24 (1) ◽

pp. 1-8

Author(s):

Janarul Shaikh ◽

Sudheer Kumar Yamsani ◽

Manash Jyoti Bora ◽

Sanjeet Sahoo ◽

Sreedeep Sekharan ◽

...

Keyword(s):

Soil Erosion ◽

Surface Soil ◽

Infiltration Rate ◽

Cover System ◽

Testing Period ◽

Antecedent Moisture ◽

Soil Systems ◽

Erosion Behaviour ◽

Landfill Cover System ◽

Control Erosion

Abstract Rainwater-induced erosion in green geotechnical infrastructures such as a multilayered landfill cover system (MLCS) is a severe concern in the current era. Although vegetation is a proven measure to control erosion in the MLCS, there are other factors such as infiltration rate which influence the control of the phenomenon. Most of the existing studies are limited to understand influence of vegetation on erosion control or infiltration rate alone. In this study, an attempt is made to incorporate infiltration measurements alongside vegetation cover to understand erosion in surface layer of the MLCS. For this purpose, a pilot MLCS was constructed, and erosion of its surface soil was temporally evaluated through soil loss depth of eroded cover surface under the influence of natural as well as simulated rainfall conditions. Alongside erosion, the amount of vegetated cover was evaluated through photographic image analyses and infiltration rate was measured by mini disk infiltrometer. From the observed results, it is understood that soil erosion and infiltration rate depict a contrasting behaviour with growing vegetation. Antecedent moisture contents were observed to show greater influence on such erosion behaviour which was observed during the testing period. Such studies may be helpful to researchers and practicing engineers for understanding performance of various green geotechnical infrastructures and scheduling the maintenance services to increase the longevity of their layered soil systems.

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A collection system for measuring runoff and soil erosion with a mobile rainfall simulator on sealed and stony red earth soils

Soil Research ◽

10.1071/sr9920457 ◽

1992 ◽

Vol 30 (4) ◽

pp. 457

Author(s):

RSB Greene ◽

GR Sawtell

Keyword(s):

Soil Erosion ◽

Hydraulic Properties ◽

Surface Soil ◽

The Other ◽

Soil Hydraulic Properties ◽

Collection System ◽

Rainfall Simulator ◽

Red Earth ◽

Soil Hydraulic ◽

Minimum Disturbance

A collection system was developed for use with a Grierson and Oades rainfall simulator. The collection system enabled measurements of runoff and soil erosion to be made on massive red earth soils with severe seals (or crusts) and stones at their surface. In our design, the collection flume was separated from the other three sides of the plot frame. This allowed the collection flume to be initially inserted with minimum disturbance to the soil hydraulic properties and then connected to the other three sides of the plot frame. Runoff data obtained with this collection system, from a stony, sealed, surface soil, are presented.

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Soil erosion in the marginal upland of Inopacan, Leyte

Annals of Tropical Research ◽

10.32945/atr39sa9.2017 ◽

2017 ◽

pp. 115-124 ◽

Cited By ~ 1

Author(s):

Faustino Villamayor ◽

Victor Asio ◽

Arjay Lerios ◽

Luz Asio ◽

Jessie Sabijon

Keyword(s):

Soil Erosion ◽

Soil Structure ◽

Surface Soil ◽

Field Application ◽

Chicken Manure ◽

Field Soil ◽

Crop Cover ◽

Erosion Rates ◽

Soil Erosion Rates ◽

Field Indicators

There is an urgent need for soil erosion data from marginal uplands in the country. This study evaluated the occurrences of soil erosion in the marginal uplands of lnopacan, Leyte. Field soil erosion indicators were assessed in different portions of the study site and erosion plots were established in the corn and sweetpotato fertilizer experiments to measure erosion rates. Field indicators of soil erosion such as rills, cracks across slopes, exposed rocks, thin surface soil and eroded sediments in waterways were common in various parts of the marginal upland studied. Soil erosion rates measured on erosion plots were higher from the corn field than from the sweetpotato field. Application of chicken manure and vermicast resulted in lower soil erosion rates due to improved soil structure. Plots without crop cover gave the highest erosion rates. The degree of soil erosion in the marginal upland can be considered as moderate to severe.

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Soil organic carbon and nitrogen losses due to soil erosion and cropping in a sloping terrace landscape

Soil Research ◽

10.1071/sr14151 ◽

2015 ◽

Vol 53 (1) ◽

pp. 87 ◽

Cited By ~ 23

Author(s):

J. H. Zhang ◽

Y. Wang ◽

F. C. Li

Keyword(s):

Soil Erosion ◽

Organic Carbon ◽

Soil Organic Carbon ◽

Surface Soil ◽

Soil Horizon ◽

Small Scale ◽

Cultivated Land ◽

N Losses ◽

Uncultivated Land ◽

Cultivated Soils

Effects of soil erosion and cropping on soil organic carbon (SOC) stocks need to be addressed to better understand the processes of SOC loss following the conversion of natural ecosystems to agriculture. The aims of the present study were to: (1) understand the mechanism of SOC and total nitrogen (TN) losses in a small-scale agricultural landscape with sloping terraces; and (2) quantitatively assess vertical changes in SOC and TN of soil profiles at specific landscape positions and the lateral distribution of SOC and TN in areas with different soil erosion and deposition rates. Soil samples from cultivated land were collected at 5-m intervals along toposequences in different parts of hilly areas of the Sichuan Basin, China; uncultivated land was used as a reference for 137Cs, SOC and TN. The profile shape of SOC and total N depth distribution was markedly different between cultivated and uncultivated soils, with differences in descriptive coefficients of 2.1–3.4- and 2.0–3.2-fold for a, 1.2–2.2- and 1.0–1.8-fold for b, respectively, in the equation y = –aln(x) + b, where y is the depth SOC or TN concentration and x is the depth from the soil surface. SOC and TN concentrations in the surface soil horizon were significantly higher on uncultivated land (17.5 g kg–1) than on cultivated land (7.06–9.81 g kg–1). In particular, the 0–5 cm surface layer of uncultivated soils had 1.3-, 1.7-, and 2.3-fold higher SOC concentrations than that of the depositional, weak erosional and strong erosional areas, respectively, in cultivated soils. However, there were no significant differences in SOC and TN concentrations in subsoil layers between cultivated and uncultivated lands, suggesting that cropping is one of the factors causing SOC and N losses. SOC and TN inventories exhibited an increasing trend from the upper to toe proportions of the cultivated toposequences. In all the cultivated soils, SOC and TN concentrations of the surface soil horizon and inventories of SOC and TN were closely associated with 137Cs inventories (P < 0.001, P < 0.01, P < 0.0001 and P < 0.0001, respectively), suggesting that soil erosion has an important impact on SOC and TN dynamics in the cultivated landscape. The results of this study suggest that soil erosion and cropping result in SOC and N losses, and that soil erosion contributes to marked variations in SOC and N distribution along the slope transect within individual sloping terraces, as well as in the entire landscape.

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