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Abstract. In situ cosmogenic 14C (in situ 14C) in quartz provides a recently developed tool to date exposure of bedrock surfaces of up to ∼ 25 000 years. From outcrops located in east-central Sweden, we tested the accuracy of in situ 14C dating against (i) a relative sea level (RSL) curve constructed from radiocarbon dating of organic material in isolation basins and (ii) the timing of local deglaciation constructed from a clay varve chronology complemented with traditional radiocarbon dating. Five samples of granitoid bedrock were taken along an elevation transect extending southwestwards from the coast of the Baltic Sea near Forsmark. Because these samples derive from bedrock outcrops positioned below the highest postglacial shoreline, they target the timing of progressive landscape emergence above sea level. In contrast, in situ 14C concentrations in an additional five samples taken from granitoid outcrops above the highest postglacial shoreline, located 100 km west of Forsmark, should reflect local deglaciation ages. The 10 in situ 14C measurements provide robust age constraints that, within uncertainties, compare favourably with the RSL curve and the local deglaciation chronology. These data demonstrate the utility of in situ 14C to accurately date ice sheet deglaciation, and durations of postglacial exposure, in regions where cosmogenic 10Be and 26Al routinely return complex exposure results.
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Bedrock cosmogenic radionuclide and noble gas measurements from the McMurdo Dry Valleys
This dataset contains (1) metadata about bedrock samples in the McMurdo Dry Valleys collected during a 2022 field season, (2) concentrations of cosmogenic radionuclides (Be-10 and Al-26) in quartz from these bedrock samples, and (3) concentrations of helium isotopes (He-3 and He-4) in quartz from these bedrock samples. All cosmogenic nuclide measurements took place at Purdue University.
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- Award ID(s):
- 1935945
- PAR ID:
- 10650743
- Publisher / Repository:
- U.S. Antarctic Program (USAP) Data Center
- Date Published:
- Edition / Version:
- 1
- Subject(s) / Keyword(s):
- Aluminum-26 Beryllium-10 Cosmogenic Isotopes Cosmogenic Radionuclides Helium Isotopes Bedrock Cryosphere
- Format(s):
- Medium: X
- Sponsoring Org:
- National Science Foundation
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