Abstract
Organic wastes have a positive impact on soil physical and chemical properties in the agroecosystems. However, its main effects on soil organic carbon (SOC) or total organic carbon, TOC (SOC and coal-C) contents as well as their effects on soil physico-chemical properties are still unclear. Two types of organic wastes (maize straw and manure) were utilized in dryland affected by mining activities to quantify their relative effect on soil physico-chemical properties. Regression analysis was used to assess the relationship between the soil physical properties, SOC, and TOC as well as their respective contributions to improving these properties. Treatments included control (CK), straw (S), low manure (LM), medium manure plus straw (S-MM), and high manure plus straw (S-HM). The results showed that SOC, soil bulk density, mean weight diameter (MWD), soil total porosity, soil penetration resistance, saturated hydraulic conductivity, and soil infiltration rate were strongly influenced by the application of organic wastes. A stronger linear relationship between SOC and the MWD, (R2 = 0.93, p < 0.05) compared to that between TOC and MWD indicated the important role of SOC in improving soil aggregation relative to the effect of TOC. According to the principal component analysis (PCA), the application of organic wastes had stronger effects on SOC contents and physical properties than TOC (SOC and coal-C). These findings advance our understanding of the actual effect of organic wastes on soil physical properties and SOC in dryland affected by mining activities and could inform fertilizer management decisions to improve soil properties.
Highlights
The economic importance of extracting surface coal mining near agricultural areas, these mining activities lead to the transformation of large areas of arable land into unproductive or low-productivity soil [1,2]
Total organic carbon content (TOC) that includes both soil organic carbon and coal carbon (coal-C) constantly increased with the application of organic wastes
The the organic carbon (TOC) content significantly increased in the S-HM treatment, while it showed an insignificant increase in the other treatments (S-MM, S, and low manure (LM)) compared to CK treatment in both soil layers (Table 3)
Summary
The economic importance of extracting surface coal mining near agricultural areas, these mining activities lead to the transformation of large areas of arable land into unproductive or low-productivity soil [1,2]. These mining processes lead to the removal of Sustainability 2021, 13, 5686. In China, these soils located near coal mining areas are typically used for the production of crops to achieve the goal of balancing needs and population growth through increased arable soils [3,4]. Previous studies have shown that mine soils have low organic carbon, high bulk density, poor structure, and low water conductivity [2,5,9]
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