Mechanism and Evolution of Soil Organic Carbon Coupling with Rocky Desertification in South China Karst

Wang, Xingfu; Huang, Xianfei; Xiong, Kangning; Ji-wei, HU; Zhang, Zhenming; Zhang, Jiachun

doi:10.3390/f13010028

Cited by 13 publications

(3 citation statements)

References 35 publications

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“…There was high discrepancy in soil nutrients and micro-C content and spatial distribution between gaps and forest, these results were close to Wang's research [48] which is adjacent to this study area. The distribution regular of different soil nutrient factors were greater diffrences between gaps and forest as well.…”

Section: Physiochemical Variation Of Gaps Along With Gap Size In Pinu...supporting

confidence: 85%

Effects of Gaps on Soil Nutrients and Soil Microbial Carbon in a <i>Pinus massoniana</i> Forest, Southwestern China

Xue¹,

Ding²

2022

Pol. J. Environ. Stud.

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To study the influences of gap size on the variation in soil nutrients, soil microbial carbon (micro-C), soil samples from Pinus massoniana forests were collected in and around different forest gaps with size ranging from 40.38 to 1321.40 m 2 in Guizhou Province. The soil nutrients (include SOC, TP, TK, TKN, valid-P, valid-K and hydro-N) and micro-C in soil samples were analyzed, and the artificial neural networks was employed to explore the importance of different soil nutrients and gap size concerning micro-C. The results indicate that the micro-C gap ranged from 38.00 to 660.32 mg kg -1 with a mean value of 221.24 mg kg -1 , and the micro-C forest ranged from 110.70 to 685.62 mg kg -1 with a mean value of 356.16 mg kg -1 . The micro-C gap /micro-C forest values increased with the increase of gap size in the range from 40 to 600 m 2 , and this trend inversed when gap size was greater than 600 m 2 . Micro-C was mainly associated with valid-P for both gaps and surrounding forests, large gap may lead to the loss of soil N. The results suggested that: (a) SOC, TK, TKN, hydro-N and valid-P are important factors to microbial in forest soils; (b) TP, valid-K, TKN, TK, valid-P and SOC are important factors to microbial in gap soils. In summary, gaps can increase the heterogeneity of soil nutrients and soil microbial, valid-P is a key factor affecting microbial abundance for Pinus massoniana forest. These promote the preservation of biodiversity and pedodiversity.

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Section: Physiochemical Variation Of Gaps Along With Gap Size In Pinu...supporting

confidence: 85%

Effects of Gaps on Soil Nutrients and Soil Microbial Carbon in a <i>Pinus massoniana</i> Forest, Southwestern China

Xue¹,

Ding²

2022

Pol. J. Environ. Stud.

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“…Long-term artificial plant restoration can significantly improve the soil aggregate stability and encourage nutrient buildup, which is of practical significance for ecosystem vegetation restoration and land use regulation in karst areas. However, the ecological environment of the southwest karst region is complex, and many factors affect the soil environment [52]. Therefore, in subsequent studies, multiple sampling can be performed to increase the number of comparative experiments in the time scale and to explore the variability of the dual spatial and temporal scales.…”

Section: Limitations and Prospectsmentioning

confidence: 99%

Afforestation Influences Soil Aggregate Stability by Regulating Aggregate Transformation in Karst Rocky Desertification Areas

Zhu

Qin-ke

Zhao

et al. 2023

Forests

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Surface vegetation has a substantial impact on soil aggregate stability, which is an important indicator of soil quality. However, there is still limited research on the response of soil aggregate stability indicators and the organic carbon, total nitrogen, and total phosphorus content in soil aggregates for different vegetation patterns in rocky desertification fragile ecological areas. Therefore, in order to study the effects of different vegetation restoration models on soil aggregate stability and aggregate related nutrient content and their promoting relationships in the karst rocky desertification areas in southwest China, soil samples under three artificial restoration vegetation measures (Juglans regia L.- Rosa roxburghii Tratt., Rosa roxburghii Tratt.- Lolium perenne L., Juglans regia L.- Lolium perenne L.) were collected in 0–10 cm and 10–20 cm soil, and the traditional farmland (Zea mays L.) was used as the control, combined with dry and wet sieving experiments for the research and analysis. The results showed that there were significant differences in the distribution of aggregates and soil nutrients among the four types of plots. Compared with traditional agricultural land, artificial afforestation increased the content of soil large macroaggregates (LMAs) and decreased the proportion of microaggregates (MIAs) and silt+clay (SCA), which enhanced the soil aggregate stability and reduced the soil fragmentation and erodibility. The afforestation restoration increased the content of soil aggregate-related SOC, TN, and TP, and increased with the decrease in the aggregate particle size. Research has found that soil aggregate stability indicators are significantly influenced by the particle size distribution of soil aggregates. In the positive succession process of vegetation types, soil nutrient accumulation is controlled by changes in the soil aggregate particle size, which affects the soil aggregate stability and reduces soil erodibility, thereby protecting the soil nutrient loss. The composite management of forest and irrigation in degraded ecological areas has certain reference and indicative significance for ecological restoration in rocky desertification areas.

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“…Wang et al indicated that rock outcrops controlled the SOC contents in the studied regions. The slope position, gradient and aspect influenced the composition and distribution of vegetation, which influenced the evolution of rocky desertification [9]. Pan et al showed that the variations in these five parameters of fine root were mainly explained by root nutrients and the interactive effects between fine root and soil nutrients [10].…”

mentioning

confidence: 99%

Plant–Soil Interactions in Karst Regions

Zhang

2023

Forests

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Mechanism and Evolution of Soil Organic Carbon Coupling with Rocky Desertification in South China Karst

Cited by 13 publications

References 35 publications

Effects of Gaps on Soil Nutrients and Soil Microbial Carbon in a <i>Pinus massoniana</i> Forest, Southwestern China

Effects of Gaps on Soil Nutrients and Soil Microbial Carbon in a <i>Pinus massoniana</i> Forest, Southwestern China

Afforestation Influences Soil Aggregate Stability by Regulating Aggregate Transformation in Karst Rocky Desertification Areas

Plant–Soil Interactions in Karst Regions

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