Tree species identity drives the vertical distribution of soil carbon and nutrient concentrations in the Loess Plateau, China

Aims Afforestation is considered an effective strategy to improve soil carbon (C) and fertility in degraded drylands. However, how specific species identities (e.g., conifers or broadleaves) impact C and nutrient concentrations across deep soil layers remains uncertain. Methods Three most important...

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Bibliographic Details
Published in:Plant and soil 2024-08, Vol.501 (1-2), p.89-105
Main Authors: Ma, Longlong, Bai, Shahla Hosseini, Chen, Ji, Lucas-Borja, Manuel Esteban, Yue, Chao, Deng, Lei, Zheng, Yuxiong, Bell, Stephen M., Hu, Zhenhong
Format: Article
Language:English
Subjects:
Afforestation
Agriculture
Ammonia
ammonium nitrogen
arid lands
Arid zones
Biomass
Biomedical and Life Sciences
Carbon
China
Coniferous forests
Conifers
Continental interfaces, environment
Ecology
Fertility
fine roots
Geographical distribution
Indigenous species
Introduced plants
Introduced species
Life Sciences
microbial biomass
Microorganisms
nitrate nitrogen
Nitrogen
Nitrogen fixation
Nitrogenation
Nutrient concentrations
Ocean, Atmosphere
Organic carbon
Organic soils
Pinus tabuliformis
Plant Physiology
Plant Sciences
Plant species
Plantations
Research Article
Robinia pseudoacacia
Sciences of the Universe
Soil improvement
Soil layers
Soil mixtures
Soil nutrients
soil organic carbon
Soil profiles
Soil properties
Soil Science & Conservation
Soils
spatial distribution
species
total nitrogen
total phosphorus
trees
Vertical distribution
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Summary:Aims Afforestation is considered an effective strategy to improve soil carbon (C) and fertility in degraded drylands. However, how specific species identities (e.g., conifers or broadleaves) impact C and nutrient concentrations across deep soil layers remains uncertain. Methods Three most important plantation forests, including plantations of native mono-species Pinus tabuliformis (coniferous species), exotic mono-species Robinia pseudoacacia (broadleaf and nitrogen-fixing species), and their mixed, were selected to explore their effects on soil organic C (SOC) and nutrient concentrations throughout soil profile (0–200 cm) in the Loess Plateau. Results The results showed that soil C and nutrient concentrations were strongly affected by species identity. Specifically, R. pseudoacacia contained significantly higher SOC, total nitrogen (N), and ammonia N concentrations than other plantations at the top layer (0–60 cm), but R. pseudoacacia contained lower total phosphorus (P) concentrations than other plantations. In the deep layer (60–200 cm), R. pseudoacacia contained lower total N, nitrate N, and total P concentrations than other plantations. There was no significant difference in SOC concentration among plantation types in the deep layer. We found antagonistic effects of tree mixtures on soil P in the top and deep layers. Furthermore, microbial biomass C and N was the primary driver of SOC and N concentration in the top layer, respectively. Conversely, fine root biomass was the primary factor influencing N and P concentrations in the deep layer. This suggests that planting exotic R. pseudoacacia with higher root biomass has the potential to exacerbate soil N and P depletion in the deep layer. Conclusion Our work emphasizes the key role of species identities in regulating soil nutrient concentrations, especially in the deep layer, and the importance of tree species selection in dryland afforestation.
ISSN:0032-079X
1573-5036
DOI:10.1007/s11104-023-06457-x