Soil particle size distribution characteristics of different land-use types in the Funiu mountainous region

•PSD can be used to quantitatively describe different soil textures.•The fractal characteristics of soil PSD between the sloping farmland and other land-use types are analyzed.•There were clear differences between the DV and Dq of soil PSD in different land-use types.•The fine particles loss is impo...

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Published inSoil & tillage research Vol. 184; pp. 45 - 51
Main Authors Qi, Fei, Zhang, Ronghua, Liu, Xia, Niu, Yong, Zhang, Hongda, Li, Huan, Li, Jiazuo, Wang, Baoyi, Zhang, Guangcan
Format Journal Article
LanguageEnglish
Published Elsevier B.V 01.12.2018
Subjects
agricultural land
agricultural soils
China
clay
forest land
Fractal dimension
fractal dimensions
granite
land use
Land-use type
mountains
Multifractal
particle size
particle size distribution
roughness
sand
silt
soil erosion
soil fertility
soil heterogeneity
Soil particle distribution
soil texture
terracing
tillage
China
Soil particle distribution
Fractal dimension
Land-use type
Multifractal
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Abstract •PSD can be used to quantitatively describe different soil textures.•The fractal characteristics of soil PSD between the sloping farmland and other land-use types are analyzed.•There were clear differences between the DV and Dq of soil PSD in different land-use types.•The fine particles loss is important cause of coarsening and increased inhomogeneity of the sloping farmland.•The results provide a soil fractal index for the degradation of soil properties in landscapes prone to soil erosion. Soil particle composition is one of the main physical properties of soil that affects soil fertility, and the fractal dimension of soil particle size distribution (PSD) can be used to quantitatively evaluate the particle composition of different soils. The single fractal dimension of soil PSD can quantitatively characterize the roughness of the soil particle, and the multifractal dimension of soil PSD can quantitatively characterize the inhomogeneous property of soil particle composition. Sloping farmland is widely distributed in hilly areas of China that are subject to the most serious soil erosion, and the loss of soil will lead to changes in soil particle composition and soil physical properties. Previous studies have not been used to evaluate the heterogeneity of soil PSD between sloping farmland and other land use types by the multifractal method. In order to quantitatively assess the differences in soil properties between the slope land and other types of land use, this paper takes four types of land use (sloping farmland, shrub-grass sloping land, terraced farmland, and oak forestland) in the warm-temperate granite mountainous areas in eastern central China as research objects. A laser particle size analyzer and soil fractal model were applied to compare the soil PSD of different land-use types and their corresponding single fractal dimension (Dv) and generalized fractal dimension (Dq). The results showed that there were clear differences between the DV and Dq of soil PSD in different land-use types. The Dv of the soil PSD increased as follows: sloping farmland < level terraced land < shrub-grass sloping land < oak forestland, indicating that the soil particle composition coarseness was highest in sloping farmland and lowest in the oak forestland. The sequence of characteristic parameters of Dq (capacity dimension, D0; information dimension, D1; and correlation dimension D2) was as follows: sloping farmland < level terraced land < shrub-grass sloping land < oak forestland, indicating that the inhomogeneity of soil particle composition was the highest in sloping farmland, and lowest in oak forestland. The Dv, D0, D1, and D2 of the soil PSD were significantly positively correlated to the content of clay and silt particles, and were significantly and negatively correlated to the content of sand particles, indicating that the fewer clay particles and silt in the soil or the higher the proportion of sand, the higher the coarseness and the inhomogeneity of soil particle composition. This study showed that the soil coarseness and the inhomogeneity of the sloping farmland soil particle composition are significantly greater than those of other land-use types. The mass loss of the soil fine particles (clay and silt particles) is an important cause of coarsening and increased inhomogeneity of the sloping farmland. This study provides a soil fractal index for quantitative assessment of soil texture and the degradation of soil properties in landscapes prone to soil erosion such as sloping farmland.
AbstractList Soil particle composition is one of the main physical properties of soil that affects soil fertility, and the fractal dimension of soil particle size distribution (PSD) can be used to quantitatively evaluate the particle composition of different soils. The single fractal dimension of soil PSD can quantitatively characterize the roughness of the soil particle, and the multifractal dimension of soil PSD can quantitatively characterize the inhomogeneous property of soil particle composition. Sloping farmland is widely distributed in hilly areas of China that are subject to the most serious soil erosion, and the loss of soil will lead to changes in soil particle composition and soil physical properties. Previous studies have not been used to evaluate the heterogeneity of soil PSD between sloping farmland and other land use types by the multifractal method. In order to quantitatively assess the differences in soil properties between the slope land and other types of land use, this paper takes four types of land use (sloping farmland, shrub-grass sloping land, terraced farmland, and oak forestland) in the warm-temperate granite mountainous areas in eastern central China as research objects. A laser particle size analyzer and soil fractal model were applied to compare the soil PSD of different land-use types and their corresponding single fractal dimension (Dᵥ) and generalized fractal dimension (Dq). The results showed that there were clear differences between the DV and Dq of soil PSD in different land-use types. The Dᵥ of the soil PSD increased as follows: sloping farmland < level terraced land < shrub-grass sloping land < oak forestland, indicating that the soil particle composition coarseness was highest in sloping farmland and lowest in the oak forestland. The sequence of characteristic parameters of Dq (capacity dimension, D₀; information dimension, D₁; and correlation dimension D₂) was as follows: sloping farmland < level terraced land < shrub-grass sloping land < oak forestland, indicating that the inhomogeneity of soil particle composition was the highest in sloping farmland, and lowest in oak forestland. The Dᵥ, D₀, D₁, and D₂ of the soil PSD were significantly positively correlated to the content of clay and silt particles, and were significantly and negatively correlated to the content of sand particles, indicating that the fewer clay particles and silt in the soil or the higher the proportion of sand, the higher the coarseness and the inhomogeneity of soil particle composition. This study showed that the soil coarseness and the inhomogeneity of the sloping farmland soil particle composition are significantly greater than those of other land-use types. The mass loss of the soil fine particles (clay and silt particles) is an important cause of coarsening and increased inhomogeneity of the sloping farmland. This study provides a soil fractal index for quantitative assessment of soil texture and the degradation of soil properties in landscapes prone to soil erosion such as sloping farmland.
•PSD can be used to quantitatively describe different soil textures.•The fractal characteristics of soil PSD between the sloping farmland and other land-use types are analyzed.•There were clear differences between the DV and Dq of soil PSD in different land-use types.•The fine particles loss is important cause of coarsening and increased inhomogeneity of the sloping farmland.•The results provide a soil fractal index for the degradation of soil properties in landscapes prone to soil erosion. Soil particle composition is one of the main physical properties of soil that affects soil fertility, and the fractal dimension of soil particle size distribution (PSD) can be used to quantitatively evaluate the particle composition of different soils. The single fractal dimension of soil PSD can quantitatively characterize the roughness of the soil particle, and the multifractal dimension of soil PSD can quantitatively characterize the inhomogeneous property of soil particle composition. Sloping farmland is widely distributed in hilly areas of China that are subject to the most serious soil erosion, and the loss of soil will lead to changes in soil particle composition and soil physical properties. Previous studies have not been used to evaluate the heterogeneity of soil PSD between sloping farmland and other land use types by the multifractal method. In order to quantitatively assess the differences in soil properties between the slope land and other types of land use, this paper takes four types of land use (sloping farmland, shrub-grass sloping land, terraced farmland, and oak forestland) in the warm-temperate granite mountainous areas in eastern central China as research objects. A laser particle size analyzer and soil fractal model were applied to compare the soil PSD of different land-use types and their corresponding single fractal dimension (Dv) and generalized fractal dimension (Dq). The results showed that there were clear differences between the DV and Dq of soil PSD in different land-use types. The Dv of the soil PSD increased as follows: sloping farmland < level terraced land < shrub-grass sloping land < oak forestland, indicating that the soil particle composition coarseness was highest in sloping farmland and lowest in the oak forestland. The sequence of characteristic parameters of Dq (capacity dimension, D0; information dimension, D1; and correlation dimension D2) was as follows: sloping farmland < level terraced land < shrub-grass sloping land < oak forestland, indicating that the inhomogeneity of soil particle composition was the highest in sloping farmland, and lowest in oak forestland. The Dv, D0, D1, and D2 of the soil PSD were significantly positively correlated to the content of clay and silt particles, and were significantly and negatively correlated to the content of sand particles, indicating that the fewer clay particles and silt in the soil or the higher the proportion of sand, the higher the coarseness and the inhomogeneity of soil particle composition. This study showed that the soil coarseness and the inhomogeneity of the sloping farmland soil particle composition are significantly greater than those of other land-use types. The mass loss of the soil fine particles (clay and silt particles) is an important cause of coarsening and increased inhomogeneity of the sloping farmland. This study provides a soil fractal index for quantitative assessment of soil texture and the degradation of soil properties in landscapes prone to soil erosion such as sloping farmland.
Author Wang, Baoyi
Li, Jiazuo
Li, Huan
Zhang, Ronghua
Niu, Yong
Liu, Xia
Zhang, Guangcan
Qi, Fei
Zhang, Hongda
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  surname: Qi
  fullname: Qi, Fei
  organization: Jiangsu Key Laboratory of Soil and Water Conservation and Ecological Restoration, Collaborative Innovation Center of Sustainable Forestry in Southern China of Jiangsu Province, Forestry College of Nanjing Forestry University, Nanjing, 210037, China
– sequence: 2
  givenname: Ronghua
  surname: Zhang
  fullname: Zhang, Ronghua
  organization: Shandong Provincial Key Laboratory of Soil Erosion and Ecological Restoration, Forestry College of Shandong Agricultural University, Taian, 271018, China
– sequence: 3
  givenname: Xia
  surname: Liu
  fullname: Liu, Xia
  email: liuxia@njfu.edu.cn
  organization: Jiangsu Key Laboratory of Soil and Water Conservation and Ecological Restoration, Collaborative Innovation Center of Sustainable Forestry in Southern China of Jiangsu Province, Forestry College of Nanjing Forestry University, Nanjing, 210037, China
– sequence: 4
  givenname: Yong
  surname: Niu
  fullname: Niu, Yong
  organization: Shandong Provincial Key Laboratory of Soil Erosion and Ecological Restoration, Forestry College of Shandong Agricultural University, Taian, 271018, China
– sequence: 5
  givenname: Hongda
  surname: Zhang
  fullname: Zhang, Hongda
  organization: Jiangsu Key Laboratory of Soil and Water Conservation and Ecological Restoration, Collaborative Innovation Center of Sustainable Forestry in Southern China of Jiangsu Province, Forestry College of Nanjing Forestry University, Nanjing, 210037, China
– sequence: 6
  givenname: Huan
  surname: Li
  fullname: Li, Huan
  organization: Monitoring Center Station of Soil and Water Conservation, Huaihe River Commission, Ministry of Water Resources, Bengbu, 233001, China
– sequence: 7
  givenname: Jiazuo
  surname: Li
  fullname: Li, Jiazuo
  organization: Monitoring Center Station of Soil and Water Conservation, Huaihe River Commission, Ministry of Water Resources, Bengbu, 233001, China
– sequence: 8
  givenname: Baoyi
  surname: Wang
  fullname: Wang, Baoyi
  organization: Jiangsu Key Laboratory of Soil and Water Conservation and Ecological Restoration, Collaborative Innovation Center of Sustainable Forestry in Southern China of Jiangsu Province, Forestry College of Nanjing Forestry University, Nanjing, 210037, China
– sequence: 9
  givenname: Guangcan
  surname: Zhang
  fullname: Zhang, Guangcan
  organization: Shandong Provincial Key Laboratory of Soil Erosion and Ecological Restoration, Forestry College of Shandong Agricultural University, Taian, 271018, China
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Snippet •PSD can be used to quantitatively describe different soil textures.•The fractal characteristics of soil PSD between the sloping farmland and other land-use...
Soil particle composition is one of the main physical properties of soil that affects soil fertility, and the fractal dimension of soil particle size...
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StartPage 45
SubjectTerms agricultural land
agricultural soils
China
clay
forest land
Fractal dimension
fractal dimensions
granite
land use
Land-use type
mountains
Multifractal
particle size
particle size distribution
roughness
sand
silt
soil erosion
soil fertility
soil heterogeneity
Soil particle distribution
soil texture
terracing
tillage
Title Soil particle size distribution characteristics of different land-use types in the Funiu mountainous region
URI https://dx.doi.org/10.1016/j.still.2018.06.011
https://www.proquest.com/docview/2116921704
Volume 184
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