Spatial variations and the key driving factors of soil losses on dolomite slopes

doi:10.13287/j.1001-9332.202302.023

Abstract

Abstract: We selected a typical dolomite slope and set up three micro-plots (projection length was 2 m, width was 1.2 m) on the upper, middle, and lower slopes to analyze the variations of soil losses and the key influencing factors during two hydrological years (2020-2021). The results showed that soil losses at different slope positions on dolomite slopes followed an order of semi-alfisol in lower slopes (386 g·m^-2·a^-1) > inceptisol in middle slopes (77 g·m^-2·a^-1) > entisol in upper slopes (48 g·m^-2·a^-1). Downward along the slope, the positive correlation gradually increased between soil losses and surface soil water content, as well as rainfall, while it gradually decreased with the maximum 30 min rainfall intensity. The meteorological factors affecting soil erosion on the upper, middle and lower slopes were the maximum 30 min rainfall intensity, precipitation, average rainfall intensity and surface soil water content, respectively. Soil erosion processes on upper slopes were mainly driven by raindrop splash erosion and infiltration-excess runoff, while that on lower slopes were mainly driven by saturation-excess runoff. The volume ratio of fine soil in the soil profile was the key factor of soil losses on dolomite slopes, with an explanation rate of 93.7%. The lower slope was the key site of soil erosion in the dolomite slopes. Subsequent rock desertification management should be based on the erosion mechanism of different slope positions, while control measures should be arranged according to local conditions.

Key words: toposequence, catena, calcareous soil, dolomite, soil profile, runoff generation mechanism, water erosion process

MENG Qingmei, FU Zhiyong, DENG Yusong, CHEN Hongsong. Spatial variations and the key driving factors of soil losses on dolomite slopes[J]. Chinese Journal of Applied Ecology, 2023, 34(2): 377-386.

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