Lithology‐mediated soil erodibility characteristics after vegetation restoration in the karst region of Southwest China

Liang, Peining; Wang, Xing; Xu, Qinxue; Zhang, Jun; Fang, Rongjie; Fu, Zhiyong; Chen, Hongsong

doi:10.1002/ldr.4972

Cited by 4 publications

(2 citation statements)

References 73 publications

(136 reference statements)

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“…The growth of forest plantations and natural forest vegetation on chernozems led to an increase in the content of water-resistant aggregates of fractions > 5, 3-5, 2-3, 1-2 and 0.5-1.0 mm in the 0-20 cm layer and a decrease in the content of fractions 0.25-0.50 and <0.25 mm compared to ordinary chernozems under steppe vegetation. Research results by Liang et al (2023) also indicate an increase in the content of water-stable aggregates in soils during the restoration of forest vegetation. Cheng et al (2023) obtained results confirming the predominance of water-stable aggregates in the surface soil layer (0-20 cm) under the forest.…”

Section: Discussionmentioning

confidence: 87%

The influence of forest vegetation on the physical properties of chernozems in the steppe zone of Ukraine

Gorban,

Bilova,

Poleva

et al. 2024

Biosys. divers.

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Targeted changes in the physical properties of soils, including through afforestation, are an important component of land use practices that are aimed at obtaining sustainable crop yields, which is especially important for potentially highly fertile chernozem soils. The physical properties of ordinary chernozems under steppe vegetation (used as a control) and plantings of Robinia pseudoacacia L. and Quercus robur L., as well as chernozem luvosol under natural forest vegetation, were studied in the field, as well as in laboratory conditions using soil samples taken from 12 areas established within Dnipropetrovsk region (Ukraine). As a result of the study, it was established that the studied ordinary chernozems and luvic chernozems are classified as silty loam according to their granulometric composition. The growth of acacia and oak plantations led to an increase in sand content and a decrease in silt content, and the growth of natural forest vegetation contributed to an increase in sand and silt content and a decrease in clay content in black soils. The influence of forest vegetation on chernozems led in the 0–20 cm layer to an increase in the content of aggregates of fractions > 2 mm and water-resistant aggregates of fractions > 0.5 mm and a decrease in the content of aggregates of fractions < 1 mm and water-resistant aggregates of fractions < 0.5 mm compared to chernozems under steppe vegetation. The growth of forest vegetation caused a decrease in the density and density of the solid phase, and an increase in the total porosity of chernozems in the layers of 0–20 and 20–40 cm. The influence of forest vegetation on ordinary chernozems and luvic chernozems contributed to an increase in the content of available water for plants and an increase in their water permeability compared to ordinary chernozems under steppe vegetation. Ordinary chernozems under acacia and oak plantations are characterized by increased electrical resistivity, and luvic chernozems under natural forest vegetation are characterized by reduced electrical resistivity compared to ordinary chernozems under steppe vegetation. The growth of forest vegetation contributed to a decrease in the dielectric constant of chernozems. The influence of natural forest vegetation leads to more pronounced changes in the physical properties of chernozems compared to the influence of acacia and oak plantings.

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Section: Discussionmentioning

confidence: 87%

The influence of forest vegetation on the physical properties of chernozems in the steppe zone of Ukraine

Gorban,

Bilova,

Poleva

et al. 2024

Biosys. divers.

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“…The aggregate composition of soils is an important indicator of their resistance to wind erosion (Le Bissonnais et al, 2017;Zheng et al, 2023), and the water resistance of aggregates is an important indicator of resistance to water erosion (Liang et al, 2023). The aggregate composition and content of water-resistant aggregates in the soil depends on many factorsparticle size distribution (Gao & Yang, 2023), characteristics of soil organic matter (Li et al, 2017;Yang et al, 2023), type of vegetation, ecosystems and land use (Dou et al, 2020;Yang et al, 2024).…”

Section: Introductionmentioning

confidence: 99%

Mechanisms of influence of forest ecosystems on the aggregate composition and water stability of soil aggregates in the semi-arid area of southeast Ukraine

Gorban,

Poleva,

Bilova

et al. 2024

Regul. Mech. Biosyst.

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Modern processes of climate change are accompanied by a number of negative factors, which include aridization, desertification, soil degradation and erosion. The research was were carried out on the territory that is the southern border of the distribution of the late glacial phase of the Dnieper glaciation (Middle Pleistocene, 100–230 thousand years ago). The influence of forest ecosystems on the aggregate composition and water stability of soil aggregates, the features of which determine the protection of soils from erosion and other degradation processes in semiarid conditions, was assessed. It has been established that luvic chernozems of forest ecosystems are characterized by an increased content of aggregates of fractions 2–3, 1–2 and 0.5–1.0 mm, as well as water-stable aggregates of fractions > 5, 0.5–1.0 and 0.25–0.5 mm in the 0–20 cm layer compared to ordinary chernozems of steppe ecosystems. The content of soil organic matter is a determining factor on which the aggregate composition and content of water-stable aggregates in luvic chernozems of forest ecosystems depends. The existence of close direct relationships has been established between the content of soil organic matter and the content of aggregates of the 0.5–1.0 mm fraction, as well as between the content of soil organic matter and the content of water-stable aggregates of fractions 3–5, 2–3 and 1–2 mm in chernozems of steppe and forest ecosystems. The existence of close direct relationships between the sand content and the content of water-stable aggregates of fractions 3–5 and 2–3 mm was revealed. The established increase in the content of soil organic matter and sand in luvic chernozems of forest ecosystems compared to ordinary chernozems of steppe ecosystems is the reason for the improvement in the aggregate composition and the increase in the content of water-stable aggregates. This is a key aspect of increasing the resistance of soils in forest ecosystems to various negative factors, such as desertification, degradation, wind and water soil erosion.

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Effects of Land Use Change on Soil Aggregate Stability and Erodibility in the Karst Region of Southwest China

Li,

Wang,

et al. 2024

Agronomy

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Differences in land use type and chronological age affect soil properties and plant community characteristics, which may influence soil structural stability and erodibility. However, knowledge on the effects of soil physicochemical properties on soil aggregate stability and erodibility at different land use years is limited. This study selected five land use types: corn field (Year 38th-y), corn intercropped with cabbage field (Year 38th-y + b), fruit and meridian forest (Year 6th-jgl), naturally restored vegetation (Year 6th-zr), and artificial forest (Year 7th-rgl) in the karst landscape of the Chishui River Basin in Yunnan Province. We aimed to identify the influencing factors of soil stability and erodibility under different land use time series. The results indicated that the mean weight diameter (MWD), the geometric mean diameter (GMD), and soil structural stability index (SSI values) were highest in Y6th-zr and lowest in Y7th-rgl. Conversely, the erodibility K value was lowest in Y6th-zr, suggesting that the soil structure in Y6th-zr exhibited greater stability, whereas soil stability in Y7th-rgl was lower. Redundancy and throughput analyses revealed that organic carbon and water-stable aggregates > 2.0 mm content had higher vector values. Soil bulk density, total nitrogen, organic carbon, and soil texture content were the main factors contributing to soil stability variation (0.338–0.646). Additionally, total nitrogen, organic carbon, total phosphorus, and soil texture content drove the variation in K values (0.15–1.311). Natural vegetation restoration measures can enhance soil structure to a certain extent. These findings highlight changes in soil aggregate stability and erodibility over different land use durations. The research results have important theoretical and practical significance for understanding the differences in soil erosion and soil restoration under different land use patterns in the karst landscapes of southwest China.

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Lithology‐mediated soil erodibility characteristics after vegetation restoration in the karst region of Southwest China

Cited by 4 publications

References 73 publications

The influence of forest vegetation on the physical properties of chernozems in the steppe zone of Ukraine

The influence of forest vegetation on the physical properties of chernozems in the steppe zone of Ukraine

Mechanisms of influence of forest ecosystems on the aggregate composition and water stability of soil aggregates in the semi-arid area of southeast Ukraine

Effects of Land Use Change on Soil Aggregate Stability and Erodibility in the Karst Region of Southwest China

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