Effects of forest conversion into grassland on soil aggregate structure and carbon storage in Panama: evidence from soil carbon fractionation and stable isotopes
2006 | journal article. A publication with affiliation to the University of Göttingen.
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Schwendenmann, Luitgard, and Elise Pendall. "Effects of forest conversion into grassland on soil aggregate structure and carbon storage in Panama: evidence from soil carbon fractionation and stable isotopes." Plant and Soil 288, no. 1-2 (2006): 217-232. https://doi.org/10.1007/s11104-006-9109-0.
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- Authors
- Schwendenmann, Luitgard; Pendall, Elise
- Abstract
- Land-use and land-cover strongly influence soil properties such as the amount of soil organic carbon (SOC), aggregate structure and SOC turnover processes. We studied the effects of a vegetation shift from forest to grassland 90 years ago in soils derived from andesite material on Barro Colorado Island (BCI), Panama. We quantified the amount of carbon (C) and nitrogen (N) and determined the turnover of C in bulk soil, water stable aggregates (WSA) of different size classes (< 53 mu m, 53-250 mu m, 250-2000 mu m and 2000-8000 mu m) and density fractions (free light fraction, intra-aggregate particulate organic matter and mineral associated soil organic Q. Total SOC stocks (0-50 cm) under forest (84 Mg C ha(-1)) and grassland (64 Mg C ha(-1)) did not differ significantly. Our results revealed that vegetation type did not have an effect on aggregate structure and stability. The investigated soils at BCI did not show higher C and N concentrations in larger aggregates, indicating that organic material is not the major binding agent in these soils to form aggregates. Based on delta C-13 values and treating bulk soil as a single, homogenous C pool we estimated a mean residence time (MRT) of 69 years for the surface layer (0-5 cm). The MRT varied among the different SOC fractions and among depth. In 05 cm, MRT of intra-aggregate particulate organic matter (iPOM) was 29 years; whereas mineral associated soil organic C (mSOC) had a MRT of 124 years. These soils have substantial resilience to C and N losses because the > 90% of C and N is associated with mSOC, which has a comparatively long MRT.
- Issue Date
- 2006
- Journal
- Plant and Soil
- Organization
- Fakultät für Forstwissenschaften und Waldökologie ; Burckhardt-Institut ; Abteilung Waldbau und Waldökologie der Tropen
- ISSN
- 1573-5036; 0032-079X