Authors: Ali Reza Vaezi, Naser Fakori Ivand, Fereshteh Azarifam

Abstract:

Inter-rill erosion is the detachment and transfer of soil particles between the rills which occurs due to the impact of raindrops and the shear stress of shallow surface runoff. This erosion can be affected by some soil properties such as texture, amount of organic matter and stability of soil aggregates. Information on the temporal variation of inter-rill erosion during a rainfall event and the effect of soil properties on it can help develop better methods to soil conservation in the hillslopes. The importance of this study is especially grate in semi-arid regions, where the soil is weakly aggregated and vegetation cover is mostly poor. Therefore, this research was conducted to investigate the temporal variation of surface flow and inter-rill erosion and the effect of soil properties on it in some semi-arid soils. A field experiment was done in eight different soil textures under simulated rainfalls with uniform intensity. A total of twenty four plots were installed for eight study soils with three replicates in the form of a random complete block design along the land. The plots were 1.2 m (length) × 1 m (width) in dimensions which designed with a distance of 3 m from each other across the slope. Then, soil samples were purred into the plots. Rainfall simulation experiments were done using a designed portable simulator with an intensity of 60 mm per hour for 60 minutes. Runoff production and soil loss were measured during 1 hour time with 5-min intervals. Soil properties including particle size distribution, aggregate stability, bulk density, exchangeable sodium percentages (ESP) and hydraulic conductivity (Ks) were determined in the soil samples. Correlation and regression analysis was done to determine the effect of soil properties on runoff and inter-rill erosion. Results indicated that the study soils have lower both organic matter content and aggregate stability. The soils, except for coarse textured textures, are calcareous and with relatively higher ESP. Runoff production and soil loss did not occur in sand texture, which was associated with higher infiltration and drainage rates. A strong relationship was found between inter-rill erosion and surface runoff (R2 = 0.75, p < 0.01). The correlation analysis showed that surface runoff was significantly affected by some soil properties consisting of sand, silt, clay, bulk density, gravel, Ks, lime (calcium carbonate), and ESP. The soils with lower Ks such as fine-textured soils, produced higher surface runoff and more inter-rill erosion. In the soils, surface runoff production temporally increased during rainfall and finally reached a peak after about 25-35 min. Time to peak was very short (30 min) in fine-textured soils, especially clay, which was related to their lower infiltration rate.

Keywords: Erosion plot, rainfall simulator, soil properties, surface flow.

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References:

[1] Wang, L., Zhang, G. and Wang, X., 2022. Undecomposed litter mixed in the soil can increase inter-rill erosion on hillslopes: A laboratory study. Soil and Tillage Research, 219, p.105350.
[2] Wang, L., 2023. Advances in Soil Erosion Research. Scientific Research Publishing, Inc. USA.
[3] Koiter, A.J., Owens, P.N., Petticrew, E.L. and Lobb, D.A., 2017. The role of soil surface properties on the particle size and carbon selectivity of inter-rill erosion in agricultural landscapes. Catena, 153, pp.194-206.
[4] Cao, L., Zhang, K., Dai, H. and Liang, Y., 2015. Modeling inter-rill erosion on unpaved roads in the loess plateau of China. Land Degradation & Development, 26(8), pp.825-832.
[5] Shen, H., Zheng, F., Wen, L., Han, Y. and Hu, W., 2016. Impacts of rainfall intensity and slope gradient on rill erosion processes at loessial hillslope. Soil and Tillage Research, 155, pp.429-436.
[6] Huang, J., Wu, P., and Xining. Z. 2013. Effects of rainfall intensity, underlying surface and slope gradient on soil infiltration under simulated rainfall experiments, Catena, 104: 93 -102.
[7] Vilayvong, K., Yasufuku, N. and Ishikura, R., 2016. Rainfall-induced soil erosion and sediment sizes of a residual soil under 1D and 2D rainfall experiments. Procedia-Social and Behavioral Sciences, 218: 171-180.
[8] Cattan D., Lan Z.H. and David, A.B. 2012. Effect of soil physical on runoff and sediment concentration under rain, Soil Science Society of America Journal, 20(10): 531-539.
[9] Ochoa, P.A., Fries, A., Mejía, D., Burneo, J.I., Ruíz-Sinoga, J.D., Cerdà, A., 2016. Effects of climate, land cover and topography on soil erosion risk in a semiarid basin of the Andes. Catena 140:31–42.
[10] Vaezi, A. R., H. Bahrami, H. Sadeghi and M. Mahdian. 2008. Modeling the USLE K-factor for calcareous soils in northwestern Iran. Geomorphology 97(3): 414-423.
[11] Rowell, D. l. 1994. Soil Science: Methods and Application. Longman Group. Harlow, 345 PP.
[12] Bouyoucos, G. J. 1962. Hydromrter method improved for making particle size analysis of soils. Agronomy Journal, 56: 464- 466.
[13] Kemper, W.D. and Rosenau, R.C. 1986. Aggregate stability and size distribution. 425-442 pp, In: Klute, A. (ed.), Methods of Soil Analysis. ASA and SSSA, Madison, WI.
[14] Klute, A. 1986. Methods of Soil Analysis, part I, physical and mineralogical methods. SSSA publisher, Madison, Wisconsin.
[15] Thomas, G. W. 1996. Soil pH and soil acidity, 475-490 PP. In: Klute, A. (Ed.), Methods of Soil Analysis. Part 3, Chemical Methods. SSSA/ASA, Madison, Wisconsin, USA.
[16] Rhoades, J. D. 1996. Salinity: Electrical conductivity and total dissolved solids, 417-436 PP. Methods of Soil Analysis. Chemical Methods. ASA/SSSA. Madison, Wisconsin, USA.
[17] Romos, M. C. and Nacci, S. 1998. Surface aggregate stability and its relationship with the soil erodibility in the Anoia-Pened (Spain). Proceedings 16th World Congress of Soil Science. Symposium 20, Ref. 1766, ISSS-AISS-IBG-SICS 1998, pp. 8, Publicacion en CD-ROM Cirad.
[18] Pansu, M. and Gautheyrou, J. 2006. Handbook of Soil Analysis, Mineralogical, Organic and Inorganic Methods. Springer, 993 p.
[19] Jin, K., Cornelis, W.M., Gabriels, D., Schiettecatte, W., De Neve, S., Lu, J., Buysse, T., Wu, H., Cai, D., Jin, J., and Hartmann, R. 2008. Soil management effects on runoff and soil loss from field rainfall simulation. Catena. 75: 191-199.
[20] Tangchuan, L., S. Mingan, J. Yuhua, J. Xiaoxu and H. Laiming. 2018. Profile distribution of soil moisture in the gully on the northern loess plateau, China. Catena, 171:460-468.
[21] Sun, L., Zhou, J.L., Cai, Q., Liu, S. and Xiao, J., 2021. Comparing surface erosion processes in four soils from the Loess Plateau under extreme rainfall events. International Soil and Water Conservation Research, 9(4), pp.520-531.
[22] Dunne, T. and Aubry, B. F. (1986) Evaluation of Horton's theory of sheetwash and rill erosion on the basis of field experiments. In A. D. Abrahams, ed., Hillslope Processes. Boston: Allen and Unwin, 31-53.