Estimation of total erosion in cultivated Black soils in northeast China from vertical profiles of soil organic carbon

Summary It is difficult to estimate soil thickness eroded from annual erosion rates in cultivated Black soils in northeast China because of the uncertainty of the time when the soil was first cultivated for agricultural crops. Assuming soil organic carbon (SOC) profile curves for cultivated sites are the same as virgin sites before cultivation, it may be possible to estimate the total thickness of surface soils lost by erosion by vertical movement of plotted SOC profiles until those for the virgin and cultivated soils are superimposed. We collected pairs of soil samples (0–1 m) with one sample in each pair from a virgin site and the other from a nearby cultivated site in Heilongjiang province, northeast China. In undulating areas where soil erosion was moderate, the shapes of SOC distribution curves below 40 cm depth were nearly identical for both cultivated and virgin soils, but were offset vertically. This offset was attributed to the loss of surface soil by erosion in the cultivated land. By moving the distribution curve of SOC in cultivated soil downwards by 12.7 cm, we found nearly coincident curves below 45 cm for the virgin and cultivated soils. This thickness (12.7 cm) was believed to be the depth of soils that had been eroded since the onset of cultivation in Black soils in northeast China. We concluded that the amount of surface soil lost by erosion could be estimated from comparison of the vertical distribution of SOC in cultivated and virgin soils.

[1]  H. B. Rice,et al.  Effect of Applied Fertilizer on Tifton 44 Bermudagrass , 1990 .

[2]  C. Valentin,et al.  Water erosion impact on soil and carbon redistributions within uplands of Mekong River , 2005 .

[3]  Xiaohuan Yang,et al.  Black soil degradation by rainfall erosion in Jilin, China , 2003 .

[4]  C. Bayer,et al.  Organic matter storage in a sandy clay loam Acrisol affected by tillage and cropping systems in southern Brazil. , 2000 .

[5]  W. J. Vreeken Soil variability in small loess watersheds: Clay and organic carbon content , 1973 .

[6]  Tang Jie Yan Bai-xing Study on black soil erosion rate and the transformation of soil quality influenced by erosion , 2005 .

[7]  Shuguang Liu,et al.  Modeling carbon dynamics in vegetation and soil under the impact of soil erosion and deposition , 2003 .

[8]  Minggang Xu,et al.  Effects of Inorganic Fertilizer Inputs on Grain Yields and Soil Properties in a Long‐Term Wheat–Corn Cropping System in South China , 2008 .

[9]  Simon J. Ussher,et al.  Iron in the Sargasso Sea (Bermuda Atlantic Time‐series Study region) during summer: Eolian imprint, spatiotemporal variability, and ecological implications , 2005 .

[10]  R. Lal,et al.  Soil carbon dynamics in cropland and rangeland. , 2002, Environmental pollution.

[11]  Xiaoping Zhang,et al.  Using 137 Cs Tracer Technique to Evaluate Erosion and Deposition of Black Soil in Northeast China , 2006 .

[12]  C. Drury,et al.  Impact of soil redistribution in a sloping landscape on carbon sequestration in Northeast China , 2006 .

[13]  K. Van Oost,et al.  Quantifying carbon sequestration as a result of soil erosion and deposition: retrospective assessment using caesium‐137 and carbon inventories , 2007 .

[14]  R. K. Misra,et al.  Measurement and prediction of nitrogen loss by simulated erosion events on cultivated forest soils of contrasting structure , 2005 .

[15]  Zhang Jinbo,et al.  Land Use Effects on the Distribution of Labile Organic Carbon Fractions through Soil Profiles , 2006 .

[16]  A. VandenBygaart Erosion and deposition history derived by depth-stratigraphy of 137Cs and soil organic carbon , 2001 .

[17]  Kenneth R. Olson,et al.  Soil, Landscape, and Erosion Relationships in a Northwest Illinois Watershed , 1989 .

[18]  E. Jong,et al.  The importance of erosion in the carbon balance of prairie soils , 1988 .