Characteristics and influencing factors of soil preferential flow in typical stands of Karst area in southwest China

doi:10.13287/j.1001-9332.202301.020

Abstract

Abstract: The study of preferential flow phenomena in Karst areas and the identification of the main factors influencing preferential flow are of great importance for the recovery of local vegetation. The distribution of the dyeing solution in the vertical and horizontal directions was examined by field staining tracer test and image processing technique. We analyzed the total dyeing area ratio, matrix flow depth, preferential flow ratio, and length index as pre-ferential flow characteristic parameters, and 14 factors affecting preferential flow using grey correlation analysis. The results showed that there were two main types of preferential flow, funnel-shaped and dendritic, with lateral water movement occurring in the soil of typical Karst stands. The mean value of the dyeing area ratio of the understory in Karst areas was 19.4%, and that of the matrix flow depth, preferential flow ratio, and length index was 4.96 cm, 62.9%, and 385.5%, respectively. Among the 14 environmental factors influencing preferential flow, the initial soil moisture content had the strongest influence on the dyeing area ratio, the available potassium content had the most significant influence on the matrix flow depth, and available phosphorous content had the most significant influence on both the preferential flow ratio and the length index. The high degree of development and spatial variability of preferential flow under typical forest stands in Karst areas was strongly influenced by physical properties such as initial soil water content, while soil nutrient also exerts important influence on preferential flow.

Key words: preferential flow, Karst area, dye tracer experiment, grey relational degree, influencing factor.

GUAN Ning, CHENG Jin-hua, HOU Fang, ZENG He-zhou, SHEN Zi-ya, ZHAO Meng-yuan, QIN Jian-miao. Characteristics and influencing factors of soil preferential flow in typical stands of Karst area in southwest China[J]. Chinese Journal of Applied Ecology, 2023, 34(1): 31-38.

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