Abstract
Purpose
Estimates of beryllium-7 (7Be) enrichment in soil particle size fractions are important for correction in existing soil redistribution models. Little attention has been given to documenting methods of estimating 7Be enrichment and assessing differences in enrichment between soil types in the context of soil redistribution modelling. Here, we detail a method for estimating 7Be enrichment and correcting soil redistribution estimates.
Materials and methods
Beryllium from a solution of BeCl2 was adsorbed to two soils with contrasting texture using a batch procedure. Soil fractions were separated by settling according to Stokes’ Law, and samples of bulk and settled fractions were digested and analysed for Be concentration and for specific surface area.
Results and discussion
Both soils demonstrated increasing enrichment of Be with increasing specific surface area. There was a marked difference in enrichment between the soil types with the coarse soil showing greater enrichment in the finer fractions. Calculated enrichment ratios for the coarse soil more than doubled between subfractions of the <63 μm class. Failure to account for the selective transport of fractions during soil redistribution studies could incur substantial errors in soil erosion estimates.
Conclusions
Stable Be provides a practical means of estimating 7Be enrichment in soil and subsequent corrections can be incorporated into the conversion model where it is proposed that corrections should be applied to the inventory deficit at each eroding point. The marked difference in enrichment between soil types in these experiments suggested that characterising enrichment and associated correction factors should be done on a site-specific basis. Implementation of the particle size correction procedures requires additional field and laboratory data to standard application of the established soil erosion conversion model.
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Acknowledgments
This paper represents a contribution to the International Atomic Energy Agency (IAEA) Coordinated Research Programme D1.20.11 under Research Agreement IAEA contract UK/15538 to WB. The manuscript scope and clarity was greatly improved by the insightful and constructive comments of the anonymous reviewers. We are also grateful to Prof. Des Walling and Dr Qingping He for helpful and insightful discussion of particle size correction challenges.
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Taylor, A., Blake, W.H. & Keith-Roach, M.J. Estimating Be-7 association with soil particle size fractions for erosion and deposition modelling. J Soils Sediments 14, 1886–1893 (2014). https://doi.org/10.1007/s11368-014-0955-8
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DOI: https://doi.org/10.1007/s11368-014-0955-8