Xu Shizhen, Wang Chunli, Zhou Junju, Shan Haihua, Li Bingxing, Shi Wei, Zhang Dongxia, Zhu Guofeng, Yang Xuemei, Wei Wei, Ma Haiyan
College of Geography and Environmental Science, Northwest Normal University, Lanzhou, China.
Key Laboratory of Resource Environment and Sustainable Development of Oasis, Lanzhou, Gansu, China.
PLoS One. 2025 Jul 14;20(7):e0326316. doi: 10.1371/journal.pone.0326316. eCollection 2025.
The dynamics and balance of soil carbon, nitrogen, and phosphorus significantly affect soil microbial activity and plants' nutrient absorption and utilization. Understanding how different land-use types and climate fluctuations influence soil carbon, nitrogen, and phosphorus forms the basis for regional land-use optimization, scientific management, and enhancement of ecosystem service functions.This paper continuously collected soil samples from forestland, grassland, and cropland in the Binggou River Basin on the northern slope of the eastern section of the Qilian Mountains during 2018-2019. It analyzed variation patterns of soil carbon, nitrogen, and phosphorus across different land-use types in the study area and explored the impacts of land-use types and seasonal climate fluctuations on these soil elements, aiming to provide a scientific basis for soil management. Results showed that during 2018-2019, the average organic carbon content in forestland soil (48.82 g/kg) was higher than that in grassland (38.32 g/kg) and cropland (30.80 g/kg). Forestland soil had slightly higher average total nitrogen (TN) content than cropland, with grassland showing the lowest. Soil organic carbon (SOC) and TN contents in forestland and grassland were lowest in summer, while grassland's total nitrogen content peaked in summer. The average total phosphorus (TP) content in cropland soil was slightly higher than in forestland and significantly higher than in grassland. The weaker carbon-sequestration capacity of cropland soil resulted in notably lower C:N (10.13) and C:P (47.38) ratios compared to forestland and grassland. Soil C:P and N:P ratios in grassland and cropland showed relatively small seasonal fluctuations, whereas those in forestland fluctuated more drastically, reaching the highest values in autumn. Excessively high C:P reduced soil phosphorus effectiveness. Regarding the soil vertical profile, SOC and TN contents in forestland and grassland both decreased with increasing soil depth, while the three nutrients in cropland soil exhibited more complex vertical variation characteristics. Overall, converting forestland and grassland to cropland significantly reduced soil carbon-sequestration capacity, shifting them from "carbon sinks" to "carbon sources" and increasing carbon emission risks. Changes in organic matter input, tillage practices, and chemical fertilizer use altered the vertical nutrient variation patterns in cropland soil.
土壤碳、氮、磷的动态变化与平衡显著影响土壤微生物活性以及植物的养分吸收与利用。了解不同土地利用类型和气候波动如何影响土壤碳、氮、磷,是区域土地利用优化、科学管理以及增强生态系统服务功能的基础。本文于2018 - 2019年持续收集了祁连山东段北坡冰沟河流域林地、草地和农田的土壤样本。分析了研究区域内不同土地利用类型下土壤碳、氮、磷的变化模式,探讨了土地利用类型和季节性气候波动对这些土壤元素的影响,旨在为土壤管理提供科学依据。结果表明,2018 - 2019年期间,林地土壤有机碳平均含量(48.82 g/kg)高于草地(38.32 g/kg)和农田(30.80 g/kg)。林地土壤全氮(TN)平均含量略高于农田,草地最低。林地和草地的土壤有机碳(SOC)和TN含量在夏季最低,而草地全氮含量在夏季达到峰值。农田土壤全磷(TP)平均含量略高于林地,显著高于草地。农田土壤较弱的碳固存能力导致其C:N(10.13)和C:P(47.38)比值明显低于林地和草地。草地和农田土壤的C:P和N:P比值季节性波动相对较小,而林地波动更为剧烈,在秋季达到最高值。过高的C:P降低了土壤磷有效性。在土壤垂直剖面方面,林地和草地的SOC和TN含量均随土壤深度增加而降低,而农田土壤中三种养分表现出更为复杂的垂直变化特征。总体而言,将林地和草地转变为农田显著降低了土壤碳固存能力,使其从“碳汇”转变为“碳源”,增加了碳排放风险。有机质输入、耕作方式和化肥使用的变化改变了农田土壤垂直养分变化模式。
