Abstract
The redistribution of soil organic carbon (SOC) in response to soil erosion along the loess slope, China, plays an important role in understanding the mechanisms that underlie SOC’s spatial distribution and turnover. Consequently, SOC redistribution is key to understanding the global carbon cycle. Vegetation restoration has been identified as an effective method to alleviate soil erosion on the Loess Plateau; however, little research has addressed vegetation restoration’s effect on the SOC redistribution processes, particularly SOC’s spatial distribution and stability. This study quantified the SOC stock and pool distribution on slopes along geomorphic gradients in naturally regenerating forests (NF) and an artificial black locust plantation (BP) and used a corn field as a control (CK). The following results were obtained: 1) vegetation restoration, particularly NF, slowed the migration of SOC and reduced the heterogeneity of its distribution effectively. The topsoil SOC ratios of the sedimentary area to the stable area were 109%, 143%, and 210% for NF, BP, and CK, respectively; 2) during migration, vegetation restoration decreased the loss of labile organic carbon by alleviating the loss of dissolved organic carbon (DOC) and easily oxidized organic carbon (EOC). The DOC/SOC in the BP and NF increased significantly and was 13.14 and 17.57 times higher, respectively, than that in the CK (p < 0.05), while the EOC/SOC in the BP and NF was slightly higher than that in the CK. A relevant schematic diagram of SOC cycle patterns and redistribution along the loess slope was drawn under vegetation restoration. The results suggest that vegetation restoration in the loess slope, NF in particular, is an effective means to alleviate the redistribution and spatial heterogeneity of SOC and reduce soil erosion.
Highlights
Soil is considered the most significant terrestrial carbon sink
The Soil organic carbon (SOC) content followed the same distributions throughout the three vegetation types: sedimentary area > stable area > eroding area
Soil erosion and SOC deposition along hillslopes can lead to spatial redistribution of SOC, i.e., the removal of soils that are rich in organic carbon from source hillslopes and their accumulation at the footslope (Wang et al, 2017)
Summary
Soil is considered the most significant terrestrial carbon sink. It is a critical factor in the regulation of the global carbon cycle, as well as in the supply of pivotal ecosystem services (Muñoz-Rojas et al, 2016; Pereira et al, 2018; Brevik et al, 2020). SOC’s depletion has a negative influence on water storage capacity, soil fertility, and the supply of other significant ecosystem services, such as climate regulation, and is a major factor that leads to soil degradation (KianiHarchegani and Sadeghi, 2020). Ongoing vegetation restoration and climate change processes are having a far-reaching effect on soil carbon stocks, which creates an imbalance in carbon input/output ratios and results frequently in net releases back into the atmosphere (Haigh et al, 2019; Petrakis et al, 2020; van der Bank and Karsten, 2020). SOC is the most susceptible to changes in site conditions and is the target of most evaluations (García-Díaz et al, 2016; Yeasmin et al, 2020)
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