Heterotrophic soil respiration and carbon cycling in geochemically distinct African tropical forest soils

Heterotrophic soil respiration and carbon cycling in geochemically distinct African tropical forest soils

Heterotrophic soil respiration is an important component of the global terrestrial carbon (C) cycle, driven by environmental factors acting from local to continental scales. For tropical Africa, these factors and their interactions remain largely unknown. Here, using samples collected along topograp...

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Bibliographic Details
Published in:Soil Vol. 7; no. 2; pp. 639 - 659
Main Authors: Bukombe, Benjamin, Fiener, Peter, Hoyt, Alison M., Kidinda, Laurent K., Doetterl, Sebastian
Format: Journal Article
Language:English
Published: Göttingen Copernicus GmbH 01-10-2021
Copernicus Publications
Subjects:
African rift system
Biodiversity
Biological activity
Carbon
Carbon cycle
Carbon dioxide
Carbon sources
Decomposition
Energy resources
Energy sources
Environmental conditions
Environmental factors
Fertility
Forest soils
Geochemistry
Gradients
Hydrology
Microbial activity
Microorganisms
Nutrients
Organic carbon
Organic matter
Organic soils
Precipitation
Radiocarbon dating
Respiration
Rift valleys
Slope gradients
Soil
Soil chemistry
Soil conditions
Soil depth
Soil fertility
Soil microorganisms
Soil organic matter
Soil stability
Soil stabilization
Stocks
Subsoils
Topography
Topsoil
Tropical climate
Tropical environments
Tropical forests
Tropical soils
Valleys
Vegetation
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Summary:Heterotrophic soil respiration is an important component of the global terrestrial carbon (C) cycle, driven by environmental factors acting from local to continental scales. For tropical Africa, these factors and their interactions remain largely unknown. Here, using samples collected along topographic and geochemical gradients in the East African Rift Valley, we study how soil chemistry and fertility drive soil respiration of soils developed from different parent materials even after many millennia of weathering. To address the drivers of soil respiration, we incubated soils from three regions with contrasting geochemistry (mafic, felsic and mixed sediment) sampled along slope gradients. For three soil depths, we measured the potential maximum heterotrophic respiration under stable environmental conditions and the radiocarbon content (Δ14C) of the bulk soil and respired CO2. Our study shows that soil fertility conditions are the main determinant of C stability in tropical forest soils. We found that soil microorganisms were able to mineralize soil C from a variety of sources and with variable C quality under laboratory conditions representative of tropical topsoil. However, in the presence of organic carbon sources of poor quality or the presence of strong mineral-related C stabilization, microorganisms tend to discriminate against these energy sources in favour of more accessible forms of soil organic matter, resulting in a slower rate of C cycling. Furthermore, despite similarities in climate and vegetation, soil respiration showed distinct patterns with soil depth and parent material geochemistry. The topographic origin of our samples was not a main determinant of the observed respiration rates and Δ14C. In situ, however, soil hydrological conditions likely influence soil C stability by inhibiting decomposition in valley subsoils. Our results demonstrate that, even in deeply weathered tropical soils, parent material has a long-lasting effect on soil chemistry that can influence and control microbial activity, the size of subsoil C stocks and the turnover of C in soil. Soil parent material and its control on soil chemistry need to be taken into account to understand and predict C stabilization and rates of C cycling in tropical forest soils.
ISSN:2199-398X
2199-3971
2199-398X
2199-3971
DOI:10.5194/soil-7-639-2021