TY - JOUR
T1 - Extension of 239+240Pu sediment geochronology to coarse-grained marine sediments
AU - Kuehl, Steven A.
AU - Ketterer, Michael E.
AU - Miselis, Jennifer L.
N1 - Funding Information:
The authors acknowledge support from the Office of Naval Research award number N00014-05-1-0088 to the Virginia Institute of Marine Science (VIMS). Support for vibracoring in North Carolina was provided by the US Army Research Office (grant DAAD19-02-1-0307 ) and the US Geological Survey (Cooperative Agreement 02ERAG0034 ). The authors also wish to acknowledge the crew of the VIMS′ R/V Pelican, G. Browder Gray, and H. Wadman for assistance in the field. MEK acknowledges support from the National Science Foundation MRI award ( CHE-0118604 ) for the ICPMS instrumentation. Any use of trade names is for descriptive purposes only and does not imply endorsement by the US Government. Clark Alexander generously reviewed two versions of the manuscript, providing many constructive suggestions. Thanks also to an anonymous reviewer for valuable comments.
PY - 2012/3/15
Y1 - 2012/3/15
N2 - Sediment geochronology of coastal sedimentary environments dominated by sand has been extremely limited because concentrations of natural and bomb-fallout radionuclides are often below the limit of measurement using standard techniques. ICP-MS analyses of 239+240Pu from two sites representative of traditionally challenging (i.e., low concentration) environments provide a "proof of concept" and demonstrate a new application for bomb-fallout radiotracers in the study of sandy shelf-seabed dynamics. A kasten core from the New Zealand shelf in the Southern Hemisphere (low fallout), and a vibracore from the sandy nearshore of North Carolina (low particle surface area) both reveal measurable 239+240Pu activities at depth. In the case of the New Zealand site, independently verified steady-state sedimentation results in a 239+240Pu profile that mimics the expected atmospheric fallout. The depth profile of 239+240Pu in the North Carolina core is more uniform, indicating significant sediment resuspension, which would be expected in this energetic nearshore environment. This study, for the first time, demonstrates the utility of 239+240Pu in the study of sandy environments, significantly extending the application of bomb-fallout isotopes to coarse-grained sediments, which compose the majority of nearshore regions.
AB - Sediment geochronology of coastal sedimentary environments dominated by sand has been extremely limited because concentrations of natural and bomb-fallout radionuclides are often below the limit of measurement using standard techniques. ICP-MS analyses of 239+240Pu from two sites representative of traditionally challenging (i.e., low concentration) environments provide a "proof of concept" and demonstrate a new application for bomb-fallout radiotracers in the study of sandy shelf-seabed dynamics. A kasten core from the New Zealand shelf in the Southern Hemisphere (low fallout), and a vibracore from the sandy nearshore of North Carolina (low particle surface area) both reveal measurable 239+240Pu activities at depth. In the case of the New Zealand site, independently verified steady-state sedimentation results in a 239+240Pu profile that mimics the expected atmospheric fallout. The depth profile of 239+240Pu in the North Carolina core is more uniform, indicating significant sediment resuspension, which would be expected in this energetic nearshore environment. This study, for the first time, demonstrates the utility of 239+240Pu in the study of sandy environments, significantly extending the application of bomb-fallout isotopes to coarse-grained sediments, which compose the majority of nearshore regions.
KW - ICP-MS
KW - New Zealand
KW - North Carolina
KW - Pu
KW - Sediment geochronology
KW - Shelf sands
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U2 - 10.1016/j.csr.2012.01.016
DO - 10.1016/j.csr.2012.01.016
M3 - Article
AN - SCOPUS:84857794856
SN - 0278-4343
VL - 36
SP - 83
EP - 88
JO - Continental Shelf Research
JF - Continental Shelf Research
ER -