Abstract
Soil organic carbon (SOC) concentration is closely related to soil quality and climate change. The objectives of this study were to estimate the effects of contemporary land use on SOC concentrations at 0–20 cm depths, and to investigate the dynamics of SOC in paddy-field soil and dry-land soil after their conversion from natural wetlands (20 and 30 years ago). We investigated the dissolved organic carbon (DOC), light fraction organic carbon (LFOC), heavy fraction organic carbon (HFOC), and other soil properties (i.e., moisture content, bulk density, pH, clay, sand, silt, available phosphorous, light fraction nitrogen, and heavy fraction nitrogen) in natural wetlands, constructed wetlands, fishponds, paddy fields, and soybean fields. The results indicated that the content of DOC increased 17% in constructed wetland and decreased 39% in fishponds, and the content of HFOC in constructed wetland and fishponds increased 50% and 8%, respectively, compared with that in natural wetlands at 0–20 cm. After the conversion of a wetland, the content of HFOC increased 72% in the paddy fields and decreased 62% in the dry land, while the content of DOC and LFOC decreased in both types. In the paddy fields, LFOC and HFOC content in the topmost 0.2 m of the soil layer was significantly higher compared to the layer below (from 0.2 to 0.6 m), and there were no significant differences observed in the dry land. The findings suggest that the paddy fields can sequester organic carbon through the accumulation of HFOC. However, the HFOC content decreased 22% after 10 years of cultivation with the decrease of clay content, indicating that paddy fields need to favor clay accumulation for the purpose of enhancing carbon sequestration in the paddy fields.
Highlights
Fossil fuel combustion and land use change are the two main factors that lead to increased atmospheric carbon dioxide (CO2) concentrations [1]
We found that when natural wetlands were converted to paddy fields or dry land, the content of dissolved organic carbon (DOC) and light fraction organic carbon (LFOC) was reduced
Our research showed that heavy fraction organic carbon (HFOC) content was higher in paddy fields (PF)-20y than in PF-30y and there was no significant difference in the dry land
Summary
Fossil fuel combustion and land use change are the two main factors that lead to increased atmospheric carbon dioxide (CO2) concentrations [1]. Paddy soil is one of the most important anthropogenic sources of atmospheric methane (CH4) emission. Soil labile organic matter fractions perform a key role for the source and sink of CO2 and CH4 [4,5]. Dissolved organic carbon (DOC) is mainly composed of organic acids and water-soluble carbohydrates and is an important labile fraction of organic carbon (OC) as it is the main energy source for soil microorganisms [6]. DOC is regarded as a sensitivity index to measure the effects of land use on soil organic matter quality [7]. Based on the density of the soil organic carbon (SOC), light fraction organic carbon (LFOC) (density ≤ 1.7 g cm−3) and heavy fraction organic carbon (HFOC) (density ≥ 1.7 g cm−3) are separated [8]. As reported by Freixo, Machado, Santos, et al [14], HFOC can account for 78–96% of SOC
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