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Pace of Landscape Change and Pediment Development in the Northeastern Sonoran Desert, United States

Authors
Larson, Phillip H.Kelley, Scott B.Dorn, Ronald I.Seong, Yeong Bae
Issue Date
2016
Publisher
ROUTLEDGE JOURNALS, TAYLOR & FRANCIS LTD
Keywords
base level; desert geomorphology; landscape evolution; surface reconstruction; weathering
Citation
ANNALS OF THE AMERICAN ASSOCIATION OF GEOGRAPHERS, v.106, no.6, pp.1195 - 1216
Indexed
SSCI
SCOPUS
Journal Title
ANNALS OF THE AMERICAN ASSOCIATION OF GEOGRAPHERS
Volume
106
Number
6
Start Page
1195
End Page
1216
URI
https://scholar.korea.ac.kr/handle/2021.sw.korea/90386
DOI
10.1080/24694452.2016.1201420
ISSN
2469-4452
Abstract
Pediments of the Sonoran Desert in the United States have intrigued physical geographers and geomorphologists for nearly a century. These gently sloping bedrock landforms are a staple of the desert landscape that millions visit each year. Despite the long-lived scientific curiosity, an understanding of the processes operating on the pediment has remained elusive. In this study we revisit the extensive history of pediment research. We then apply geospatial, field, and laboratory cosmogenic Be-10 nuclide dating and back-scattered electron microscopy methods to assess the pace and processes of landscape change on pediment systems abutting the Salt River in Arizona. Our study focuses on the Usery pediments linked to base-level fluctuations (river terraces) of the Salt River. Relict pediment surfaces were reconstructed with dGPS data and kriging methodologies utilized in ArcGIS-based on preserved evidence of ancient pediment surfaces. Be-10 ages of Salt River terraces established a chronology of incision events, where calculating the volume between the reconstructed relict pediment and modern surface topography established minimum erosion rates (similar to 41 mm/ka to similar to 415 mm/ka). Pediment area and length appear to have a positive correlation to erosion rate and development of planar pediment surfaces. Field and laboratory observations reveal that pediment systems adjust and stabilize at each Salt River terrace. Relief reduction across the pediment begins with pediment channel incision via headward erosion. Next, tributary drainage capture begins and collapses interfluves. Lateral stream erosion promotes planation where the porosity of decayed granite along channel banks exceeds the bedrock underneath ephemeral channels.
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