A simulated study of surface morphological evolution on coarse-textured soils under intermittent rainfall events

• Published in: Catena (Giessen) Vol. 208; p. 105767
• Main Authors: Ni, Shimin, Wen, Hui, Wilson, G.V., Cai, Chongfa, Wang, Junguang
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 01.01.2022
• Subjects: Coarse grain coverage; Inter-rill and rill erosion; Rainfall simulation; Stream power; Surface roughness; Inter-rill and rill erosion; Rainfall simulation; Surface roughness; Stream power; Coarse grain coverage
• ISSN: 0341-8162; 1872-6887
• DOI: 10.1016/j.catena.2021.105767

[Display omitted] •Coarse-textured soil surface morphology evolution is studied by simulated rainfall.•Surface enriched coarse grains are quantified by photography and binarization.•Soil loss in inter-rill areas is controlled by surface coarse-grain coverage.•Soil clay content and stream power is shown to fit erosion prediction. The evolution of slope surface morphology directly affects the hydrological process and forms a dynamic feedback loop with the runoff and sediment production. However, the unique erosion processes and feedback mechanism for the surface morphological changes of coarse-textured granite soils have been rarely studied previously. Here, a series of rainfall simulation experiments (intensity of 90 mm h−1) were conducted under continual intermittent rainfall conditions (duration of 20 h) on a 0.8 m by 3.0 m soil flume packed with the four coarse-textured granite soils (sieved soils from the counties of Tongcheng, Ganxian, Changting, and Wuhua, China, defined as TCA, GXA, CTA and WHA, respectively) to measure the surface roughness, coarse grain coverage, soil erosion rate, stream power and sediment sorting. The results showed: 1) the coarse grain coverage of the four soils gradually increased with rainfall duration, with the final maximum (74.89%) for CTA soil, which corresponded to the enrichment of fine particles in the sediments; 2) the mean soil erosion rate of the four soils ranged from 0.090 to 0.76 kg m−2 min−1 with the decrease of clay content from 24.19% to 13.60% in the original soils, coinciding with the surface roughness controlled by rill erosion around the coarse grains; 3) the coarse grain cover provided a protective layer to reduce further soil loss in inter-rill areas; 4) the model of soil clay content and stream power was shown to be suitable for soil erosion prediction of coarse-textured soils (R2 = 0.93). The results highlighted soil mechanical composition and coarse grain coverage on the surface as the key factors affecting the coarse-textured soil erosion. This study facilitates our understanding of the unique erosion processes and the erosion feedback mechanism of coarse-textured soils.