Beryllium-7 in soils and vegetation along an arid precipitation gradient in Owens Valley, California

Beryllium‐7 is a potentially powerful tracer of atmospheric deposition and recent sediment transport, but the quantity and distribution of 7Be on arid landscapes have not been described. We measured 7Be in soil, vegetation, and dust in Owens Valley, California, and describe its distribution in aridi...

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Bibliographic Details
Published in:Geophysical research letters 2011-05, Vol.38 (9), p.np-n/a
Main Authors: Kaste, James M., Elmore, Andrew J., Vest, Kimberly R., Okin, Gregory S.
Format: Article
Language:English
Subjects:
beryllium
cosmogenic
Deposition
Dust
Earth sciences
Earth, ocean, space
Exact sciences and technology
fallout
Inventories
sediment
soil
Soils
Stockpiling
Tracers
Valleys
Vegetation
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Summary:Beryllium‐7 is a potentially powerful tracer of atmospheric deposition and recent sediment transport, but the quantity and distribution of 7Be on arid landscapes have not been described. We measured 7Be in soil, vegetation, and dust in Owens Valley, California, and describe its distribution in aridisols and mollisols to evaluate its potential as a sediment tracer in desert environments. Beryllium‐7 in vegetation and the upper few cm of soil is low but detectable (>20 Becquerels [Bq] m−2). Surface inventories of 7Be at sites on the valley floor vary by a factor of five between the end of the rainy season (April) and the end of the dry season (November). In mollisols, live grasses hold ∼50 Bq 7Be m−2, which is on the order of half of the total springtime surface inventory. We find that within‐site variability at the 5 m scale is 5 to 22% (1 relative standard error) and can be explained by localized rain shadowing and erosion, but between site variability at the km scale can be explained by differences in rainfall. Our alpine site has more than triple the inventory that is predicted from the rainfall‐7Be flux relationship that we generate using our springtime soil measurements and previously reported deposition data. Dust deposition does not appear to contribute significantly to 7Be inventories, but anomalously high 7Be on the eastern flank of the Sierras may be explained by a higher altitude air mass source and better scavenging efficiency of snow.
ISSN:0094-8276
1944-8007
DOI:10.1029/2011GL047242