Alluvial fan surfaces and an age-related stability for cultural resource preservation: Nevada Test and Training Range, Nellis Air Force Base, Nevada, USA

Surface geomorphology studies, measurements of cosmogenic 10Be concentrations, and satellite imagery analysis are employed to construct a surface stability model for the preservation of archeological features in Stonewall Flat, Nevada, USA. Primary fan processes of incised channel floods and sheet f...

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Bibliographic Details
Published in:Journal of archaeological science, reports reports, 2015-06, Vol.2, p.551-568
Main Authors: Dickerson, Robert P., Bierman, Paul R., Cocks, Gregory
Format: Article
Language:English
Subjects:
Alluvial fan
Site preservation
Surface age
Surface stability
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Summary:Surface geomorphology studies, measurements of cosmogenic 10Be concentrations, and satellite imagery analysis are employed to construct a surface stability model for the preservation of archeological features in Stonewall Flat, Nevada, USA. Primary fan processes of incised channel floods and sheet floods construct alluvial fans and secondary processes of sheetwash, eolian erosion and deposition, bioturbation, and soil development subsequently modify fan surfaces. Each process leaves distinctive surface features, but collectively darkens and smooth's the surface with age. Concentrations of cosmogenic 10Be in surface and subsurface samples for fans with recently active surfaces have effectively zero ages, whereas concentrations for fans with mature pavements have ages of 35 to 40thousandyears (ka). Surface age data from other Stonewall Flat studies indicate that fans in transition from primary process to secondary process domination are younger than 13ka, and that older fan surfaces are dominated by secondary processes. Image analysis demonstrates a correlation between fan surface darkening and age, and permits age estimations for undated surfaces. Results indicate that surfaces dominated by primary processes are younger than 3ka and unstable for the preservation of older sites; surfaces dominated by secondary processes are older than 10ka and stable for site preservation.
ISSN:2352-409X
DOI:10.1016/j.jasrep.2015.05.002