Soil Infiltration Properties Are Affected by Typical Plant Communities in a Semi-Arid Desert Grassland in China

A process of infiltration from the soil surface to form soil water is known as soil infiltration; this is the only way for plants to absorb and use soil water. This process is closely related to nutrient migration, surface runoff, and soil erosion. The objectives of this study were to quantify the e...

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Published inWater (Basel) Vol. 14; no. 20; p. 3301
Main Authors Shi, Shiling, Zhao, Feiyan, Ren, Xiaomeng, Meng, Zhongju, Dang, Xiaohong, Wu, Xiaolong
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.10.2022
Subjects
Bulk density
Climate change
Deserts
Drought
Environmental restoration
Grasslands
Hydrology
Infiltration rate
Moisture content
Organic matter
Particle size
Plant communities
plant community
Plant populations
Plant roots
Porosity
Precipitation
Rain
root properties
semi-arid desert grassland
Soil characteristics
Soil depth
Soil erosion
Soil infiltration
Soil layers
Soil management
Soil permeability
Soil porosity
Soil properties
Soil water
Surface runoff
Vegetation
Water content
Water shortages
Mongolia
China
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Summary:A process of infiltration from the soil surface to form soil water is known as soil infiltration; this is the only way for plants to absorb and use soil water. This process is closely related to nutrient migration, surface runoff, and soil erosion. The objectives of this study were to quantify the effect of typical plant communities on soil infiltration performance, reveal the interaction between soil infiltration rate and soil characteristics and plant roots, and determine the primary influencing elements on the Xilamuren grassland. The ring knife method was used to determine the soil infiltration rate at the 0–30 cm soil layer of six typical vegetation communities. The results indicated that the infiltration rate of the Koeleria macrantha community was highest at the soil depth of 0–5 cm, while that of the Convolvulus ammannii community was lowest, reaching 4.25 mm·min−1 and 0.53 mm·min−1, respectively. The soil infiltration rate of different plant communities gradually declined with the increment of soil depth. The strongest correlations were found between bulk density, total porosity, organic matter, root characteristics, and soil infiltration rate. The bulk density, initial water content, capillary porosity, and clay content were the primary influencing factors acting on soil infiltration in the region. Other factors indirectly impacted the infiltration rate by modifying bulk density, which was a crucial limiting factor determining the infiltration rate in the research region. The study’s findings will give theoretical and practical assistance for the prevention and management of soil deterioration and grassland restoration in this area.
ISSN:2073-4441
2073-4441
DOI:10.3390/w14203301