New approach to estimate the shear stress and the force of raindrops and their effect on erodibility of agricultural soils

Abderzak Moussouni, Malek Bouhadef, Liatim Mouzai

Abstract


The objective of this work was to the study the erosive force of raindrops and the shear stress on the soil erodibility of disturbed and saturated agricultural soil. A mathematical development was used to determine a new approach to the shear stress. The soil erodibility is calculated using the WEPP (water erosion prediction project) model. To realize this work, an experimental study was led in a laboratory using the rainfall simulator. The soil tray used in this study has a length of 2 m, width of 50 cm and a depth of 15 cm and the slope was adjusted with a system. The soils used were sandy and silty agricultural soils. The results show that the relationship between the erosive force of raindrops and the shear stress on the soil erodibility increased respectively as a power and linear function with an important coeffiient of determination. As regards the relationships between soil erodibility and the mean raindrop diameter, the evolution is represented by a power function with high coeffiient of determination.


Keywords


erosive force, raindrops, rainfall simulator, shear stress, soil erodibility

Full Text:

PDF

References


Abrahams, A.D., Li, G., Krishnan, C., Atkinson, J.F., 2001. A sediment transport equation for interrill overland flw on rough surfaces. Earth Surface Processes and Landforms, 26(13): 1443–1459.

Abrahams, A.D., Atkinson, J.F., 1993. Relation between grain velocity and sediment concentration in overland flows. Water Resources Research, 29(9): 3021-3028.

Bergsma, E., Charman, P., Gibbons, F., Hurni, H., Moldenhauer, W.C., Panichapong, S., 1996. Terminology for soil erosion and conservation. ISSS.

Brunori F., Penzo M.C. Torri D. F., 1989. Soil shear strength: Its measurement and soil detachability. Catena, 16: 59-71.

Bryan, B., Brun S.E., 1999. Laboratory experiments on sequential scour deposition and their application to the development of banded vegetation. Catena, 37: 147-163.

Bryan, B., Scaborough G. Govers, J. Poesen, L., 1989. The concept of soil erodibility and some problems of assessment and application. Catena, 16: 393-412.

Bryan, B., Shiu-Hung L., 1981. Laboratory experiment on the variation of soil erosion under simulated rainfall. Geoderma, 26: 245-265.

Bryan B., 1979. The influence of slope angle on soil entrainment by sheetwash and rainsplash. Earth surface processes, 4: 43-58.

Bryan B., 1976. Considerations on soil erodibility indices and sheetwash. Catena, 3 : 99-11.

Bultot F., Coppens A., 1985. Puissance d’une averse. Hydrlogical Sciences- Journal- des Sciences Hydrologiques, 30, 3, 9/1985.

Collinet, J., Valentin, C., 1984. Evaluation of factors influencing water erosion in west Africa using rainfall simulation. Challenges in African Hydrology and water Resources. IAHS Publ. no. 144.

Diaz-Zorita, M., Duart, G., Grove, H., 2002. A review of no-till systems and soil management for sustainable crop production in the sub humid and semiarid pampas of Argentina. Soil tillage res. 65, 1-28.

De Ploey, J., Savat J., 1968. Contribution to the study of splash erosion. Z. Geomorphology 12: 174-193.

Ellison, W.D., 1947. Soil erosion studies. Agricultural Engineering. V. 28, p. 402-405.

Erpul, G., Norton, L.D., Gabriels, D., 2002. Raindrop-induced and wind-driven soil particle transport. Catena, 47(3):227–243.

Farenhorst A., Bryan R.B., 1995. Particle size distribution of sediment transported by shallow flow. Catena 25, pp: 47-62.

Ferro V., 1998. Evaluating overland flow sediment transport capacity. Hydrol. Process. 12, 1895-1910.

Fox, D.M., Bryan, R.B., 1999. The relationship of soil loss by interrill erosion to slope gradient. Catena 38: 211-222.

Gimenez, R., Govers, G., 2002. Flow detachment by concentrated flow on smooth and irregular beds. Soil Science Society of America Journal, 66:1475–1483.

Govers, G., Everaert, W., Poesen, J., Rauws, G., De Ploey, J., Lautridou, J. P., 1990. A long flume study of the dynamic factors affecting the resistance of a loamy soil to concentrated flow erosion. Earth Surface Processes and Landforms, 15: 313-328.

Govers, G., 1985. Selectivity and transport capacity of thin flows in relation to rill erosion. Soil Science Society of America Journal, 12:35–49.

Graf, W., Altinakar, M., 2000. Hydraulique fluviale : écoulement et phénomènes de transport dans les canaux à géométrie simple. Presses Polytechniques et Universitaires Romandes.

Guy, B.J., Dickinson, W.T., Rudra, R.P., 1990. Hydraulics of sediment-laden sheet flow and the influence of simulated rainfall Earth surface Processes and Landforms, Vol. 15, pp: 101-118.

Hudson, N., 1995. Soil conservation, 3rd ed. 391pp, BT Batsford, London.

Kilinc, M., Richardson, E.V., 1973. Mechanics of soil erosion from overland flow generated by simulated rainfall colo. State univ., hydrologic paper, number 63, ft. Collins, Colorado. Kinnel, P. I. A., 1973. Soil conservation. Edition. Baksford. USA.

Kinnell, P.I.A., 2000. The effect of slope length on sediment concentrations associated with side-slope erosion. Soil Science Society of America Journal, 64:1004–1008.

Kinnell, P.I.A., 1993. Runoff as a factor influencing experimentally determined interrill erodibilities. Aust. J. Soil Res. 31, 333–342.

Kinnell P.I.A., Cummings D., 1993. Soil/slope gradient interactions in erosion by rain-impacted flow. Amer. Soc. of Agric. Engineers. 36:381-387.

Kinnell P.I.A., 1991. The effect of flow depth on sediment transport induced by raindrops impacting shallow flows. American society of agricultural engineers, 91:161-168.

Leguédois, S., Planchon, O., Legout, C., Le Bissonnais, Y., 2005. Splash projection distance for aggregated soils. theory and experiment. Soil Science Society of America Journal, 69(1):30–37.

Li, G., 2009. Preliminary study of the interference of surface objects and rainfall in overland flow resistance. Catena 78: 154-158.

Maaliou, A., Mouzai, L., 2018. The relation between the rainfall erosivity index AI and the hydraulics of overland flw and sediment concentration in sandy soils. Polish Journal of Soil Science, LI/1: 41–58

Moussouni, A., Mouzai, L., Bouhadef, M., 2012. Laboratory Experiments: Influence Of Rainfall Characteristics On Runoff And Water Erosion. Journal World Academy of Science, Engineering and Technology. 68:1540-1543.

Mouzai, L., Bouhadef, M., 2003. Water drop erosivity: Effects on soil splash Erosivité de la goutte d’eau: Effets sur l’arrachement des particules de sol. Journal of hydraulic research, 41(1):61-68.

Ozoko D.C., Edeani C., 2015. Relationship between Soil Erodibility, Rainfall Erosivity and Geotechnical Parameters for Soils in GullyErosion Sites inUrualla, Imo State, Nigeria. International Journal of Science and Research (IJSR). 4 (6):1848-1852.

Pan, C., Shangguan, Z., 2006. Runoff hydraulic characteristics and sediment generation in sloped grassplots under simulated rainfall conditions. Journal of Hydrology 331: 178–185.

Rauws G., Govers G., 1988. Hydraulic and soil mechanical aspects of rill generation on agricultural soils. Journal of soil science, 39: 111-124.

Rauws, G., 1987. The initiation of rills on plane beds of non-cohesive sediments. In Rill Erosion: Processes and significance (Eds. R. Bryan), Catena Supplement 8:107-118.

Riezebos , T., Epema, G., 1985. Drop shape and erosivity. Part II: Splash detachment, transport and erosivity indices. Earth surface processes and Landforms, 10(1): 69-74.

Romero, C. C., Stroosnijder L., Baigorria G. A., 2007. Interrill and rill erodibility in the northern Andean highlands catena, 70(2):105-113.

Salles, C., Poesen, J., Govers, G., 2000. Statistical and physical analysis of soil detachment by raindrop impact: Rain erosivity indices and threshold energy. Water Resources Research,

Schmidt, J., 1993. Modeling long-term soil loss and landform change. In: A.J. Parsons, A.D. Abrahams (eds.), Overland flow Hydraulics and Erosion Mechanics, UCL Press, London.

Shih H.-M., Yang, C.T., 2009. Estimating overland flow erosion capacity using unit stream power. International Journal of Sediment Research, 24(1): 46-62.

Torri, D., Sfalanga, M., and Del Sette, M., 1987. Splash detachment: runoff depth and soil cohesion. Catena, 14: 149-155.

Truman, C.C., Bradford, J.M., 1993. Relationships between rainfall intensity and the interrill soil loss-slope steepness ratio as affected by antecedent water content. Soil Science 156 (6): 405–413.

Young, R. A., Wiersma, J. L., 1973. The role of rainfall impact in soil detachment and transport. Water Resources Research, 9(6):1629–1636.

Zachar, D., 1982. Soil erosion. Developments in soil science, 10 Elsevier scientific, Amsterdam.




DOI: http://dx.doi.org/10.17951/pjss.2019.52.1.75
Date of publication: 2019-05-29 07:32:58
Date of submission: 2018-06-25 14:09:50


Statistics


Total abstract view - 693
Downloads (from 2020-06-17) - PDF - 410

Indicators



Refbacks



Copyright (c) 2019 Abderzak MOUSSOUNI, BOUHADEF Malek, MOUZAI Liatim

Creative Commons License
This work is licensed under a Creative Commons Attribution 4.0 International License.