Abstract
Residual soils (saprolites) developed on crystalline rocks appear to form by an essentially isovolumetric process (i.e. without dilation or compaction). Isovolumetric geochemical analysis of a suite of saprolite samples developed on a common parent rock can be used to estimate the relative rates of long-term losses of P and Si during weathering. Using the export of dissolved Si in rivers as a weathering index, one can then estimate the rate of P release due to chemical weathering by means of the P-Si loss ratio in saprolite. For three basins where data are available (Liberty Hill, SC; Amazon River, Brazil: Rio Negro, Brazil) estimated P weathering release rates are 163, 457, and 242 moles P km−2 yr−1 respectively. These compare to precipitation inputs of 684, 700 and 630 moles P km−2 yr−1 and total river exports of 256, 4490 and 820 moles P km−2 yr−1, respectively. The Rio Negro shows a near perfect balance between the input of P via precipitation and chemical weathering and the riverine output of dissolved and suspended P. This system, however, raised the unsolved problem of the source that supports the atmospheric P input.
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Gardner, L.R. The role of rock weathering in the phosphorus budget of terrestrial watersheds. Biogeochemistry 11, 97–110 (1990). https://doi.org/10.1007/BF00002061
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DOI: https://doi.org/10.1007/BF00002061