Please use this identifier to cite or link to this item: http://hdl.handle.net/1959.13/916979
- The 'humped' soil production function: eroding Arnhem Land, Australia
Heimsath, Arjun M.;
Hancock, Greg R.
- The University of Newcastle. Faculty of Science & Information Technology, School of Environmental and Life Sciences
- We report erosion rates and processes, determined from in situ-produced beryllium-10 (¹⁰Be) and aluminum-26 (²⁶Al), across a soil-mantled landscape of Arnhem Land, northern Australia. Soil production rates peak under a soil thickness of about 35 cm and we observe no soil thicknesses between exposed bedrock and this thickness. These results thus quantify a well-defined ‘humped’ soil-production function, in contrast to functions reported for other landscapes. We compare this function to a previously reported exponential decline of soil production rates with increasing soil thickness across the passive margin exposed in the Bega Valley, south-eastern Australia, and found remarkable similarities in rates. The critical difference in this work was that the Arnhem Land landscapes were either bedrock or mantled with soils greater than about 35 cm deep, with peak soil production rates of about 20 m/Ma under 35–40 cm of soil, thus supporting previous theory and modeling results for a humped soil production function. We also show how coupling point-specific with catchment-averaged erosion rate measurements lead to a better understanding of landscape denudation. Specifically, we report a nested sampling scheme where we quantify average erosion rates from the first-order, upland catchments to the main, sixth-order channel of Tin Camp Creek. The low (~5 m/Ma) rates from the main channel sediments reflect contributions from the slowly eroding stony highlands, while the channels draining our study area reflect local soil production rates (~10 m/Ma off the rocky ridge; ~20 m/Ma from the soil mantled regions). Quantifying such rates and processes help determine spatial variations of soil thickness as well as helping to predict the sustainability of the Earth's soil resource under different erosional regimes.
- Earth Surface Processes and Landforms Vol. 34, Issue 12, p. 1674-1684
- Publisher Link
- John Wiley & Sons
- Resource Type
- journal article