Fractal features of sandy soil particle-size distributions during the rangeland desertification process on the eastern Qinghai-Tibet Plateau

Purpose Fractal theory has been frequently applied to quantify soil particle-size distributions (PSDs) and evaluate soil degradation. Eolian desertification occurring on the eastern Qinghai-Tibet Plateau is threatening the ecological environment. It is essential to investigate the desertification pr...

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Bibliographic Details
Published in:Journal of soils and sediments 2020, Vol.20 (1), p.472-485
Main Authors: Feng, Xiao, Qu, Jianjun, Tan, Lihai, Fan, Qingbin, Niu, Qinghe
Format: Article
Language:English
Subjects:
Arithmetic
Biodegradation
Bulk density
Clay
Computer simulation
Correlation analysis
Data points
Deposition
Desertification
Dimensions
Drying
Drying ovens
Earth and Environmental Science
Ecological monitoring
Environment
Environmental Physics
Fractal geometry
Fractal models
Fractals
Lasers
Light
Nitrogen
Organic carbon
Organic soils
Oxidation
Parameters
Particle size
Potassium dichromate
Rangelands
Sand
Sandy soils
Sec 5 • Soil and Landscape Ecology • Research Article
Silt
Soil degradation
Soil density
Soil depth
Soil environment
Soil erosion
Soil moisture
Soil properties
Soil Science & Conservation
Soil testing
Soils
Sulfuric acid
Sulphuric acid
Variance analysis
Wind erosion
Wind tunnels
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Summary:Purpose Fractal theory has been frequently applied to quantify soil particle-size distributions (PSDs) and evaluate soil degradation. Eolian desertification occurring on the eastern Qinghai-Tibet Plateau is threatening the ecological environment. It is essential to investigate the desertification process by adopting the concept of space as a substitute for time. Here, the fractal features of soil PSDs and their relationships with selected soil properties and wind erosion and deposition were studied. Materials and methods The tested soil samples were collected from rangelands with four different degrees of desertification (light, medium, severe, and extremely severe). Soil particle sizes were measured by a laser diffraction particle-size analyzer. Soil moisture and soil bulk density were determined by the soil weight difference before and after oven-drying for 8 h. Soil organic carbon was determined by the K 2 Cr 2 O 7 -H 2 SO 4 oxidation method and soil total nitrogen was analyzed using the Kjeldahl digestion procedure. Wind tunnel experiments were conducted to simulate wind erosion and deposition during the desertification process. Values of the fractal dimension of soil PSDs were calculated using the volume-based fractal model. ANOVA with an LSD test and Pearson correlation analysis were used to analyze whether different parameters used in the fractal model influenced the results of the fractal dimensions and were reasonable to be applied. Results and discussion Different parameters, including the arithmetic mean size and the upper sieve size of two successive sieve sizes, values of R min , and the number of data points used in the fractal model, rarely influenced the results of the fractal dimensions ( p  > 0.05). The D values showed a significantly positive correlation with the clay and silt contents and a strong negative correlation with the sand contents. Along the degrees of desertification from light to extremely severe, the contents of clay, silt, and very fine sand decreased while the fine sand contents increased, and the D values decreased accordingly. Rangelands with heavier desertification and lower D values were more easily exposed to wind erosion, relating to the further loss of soil organic carbon, soil total nitrogen, and soil moisture and increased soil bulk density. The soil depth could affect soil PSDs and the selected soil properties of rangelands under light and medium degrees of desertification but rarely influenced those of severely
ISSN:1439-0108
1614-7480
DOI:10.1007/s11368-019-02392-6