Abstract
Soil organic carbon (SOC) is significant for soil quality and global carbon cycles. SOC was observed to be related to soil geochemistry, and soils originating from different bedrocks have different geochemical properties, but the effect of bedrock on SOC is still undefined. Soils overlying different bedrocks in Zhenxiong County and Weixin County were sampled. Specifically, soils in the mineral horizon, which are less affected by the external environment than surface soils, are focused on to reveal the effect of bedrock on SOC. Al/Ti, Fe/Ti, and Al/Fe indicate a soil–rock successive relationship. SOC contents in the mineral horizon are 0.19–2.74% (1.24% on average), and those in the surface horizon are 1.26–4.01% (2.63% on average). SOC contents in the surface and mineral horizons of the same bedrock are significantly positively correlated, implying that the bedrock is an important factor affecting SOC. SOC in the mineral horizon is related to the first transition metal ions. Significantly, positive correlations of SOC (p < 0.01) with Co, Cu, Ti, V, and Zn, and a positive correlation (p < 0.05) with Ni were observed in the mineral horizon. Organic transition metal complexation seems to play an important role in governing SOC in the mineral horizon. That is, the complexation maintains organic carbon stability, slows down its decomposition rate, and accumulates organic carbon. The Ca–SOC positive correlation in the mineral horizon exits because Ca also can complex with organic carbon. Co, Cu, and V–SOC positive correlations (p < 0.05) were also observed, but there were no significant positive correlations (p < 0.01) in the surface horizon because surface SOC had diversified sources. An SOC evolution model influenced by the bedrock was forwarded. Thus, the different soil geochemistry originating from different bedrocks should be noticed when SOC and global carbon cycles are discussed.
Highlights
Soil organic carbon (SOC) constitutes a large pool within the global carbon cycle
The ratios for limestone in the Qixia Formation of early-Permian show obvious deviations between the bedrock and the soil, which indicates that the soil does not originate from the underlying bedrock the residual texture, slope, and topography had been considered in the field
The soil geochemistry is succeeded from the bedrock in this area
Summary
Soil organic carbon (SOC) constitutes a large pool within the global carbon cycle. Soil organic carbon storage amounts deeply affect carbon dioxide (CO2) emissions to the atmosphere, and its slight change may have a significant effect on the atmospheric CO2 concentration (Schlesinger and Andrews, 2000). SOC is crucial to maintain the soil ecosystem function and quality (Raiesi, 2021). It acts as natural nutrition necessary for plant uptake and improves soil water and fertilization by altering soil’s physical, chemical, and biological properties (Six et al, 2000). The SOC content and its driving factor have been regarded as important processes in determining the soil quality and regulation of the increasing atmospheric CO2 concentration
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