Abstract
The modern Antarctic Dry Valleys are locked in a hyper-arid, polar climate that enables the East Antarctic Ice Sheet (EAIS) to remain stable, frozen to underlying bedrock. The duration of these dry, cold conditions is a critical prerequisite when modeling the long-term mass balance of the EAIS during past warm climates and is best examined using terrestrial paleoclimatic proxies. Unfortunately, deposits containing such proxies are extremely rare and often difficult to date. Here, we apply a unique dating approach to tundra deposits using concentrations of meteoric beryllium-10 (10Be) adhered to paleolake sediments from the Friis Hills, central Dry Valleys. We show that lake sediments were emplaced between 14–17.5 My and have remained untouched by meteoric waters since that time. Our results support the notion that the onset of Dry Valleys aridification occurred ~14 My, precluding the possibility of EAIS collapse during Pliocene warming events. Lake fossils indicate that >14 My ago the Dry Valleys hosted a moist tundra that flourished in elevated atmospheric CO2 (>400 ppm). Thus, Dry Valleys tundra deposits record regional climatic transitions that affect EAIS mass balance, and, in a global paleoclimatic context, these deposits demonstrate how warming induced by 400 ppm CO2 manifests at high latitudes.
Highlights
Continuous record of climate change contained within the innermost, highest elevation zone of the Dry Valleys
The Friis Hills, Taylor Valley (800 m above sea level) contains a thick (14 m) series of stacked glacial drifts found interbedded with silty paleolacustrine sediments
Cosmic-ray-produced 10Be forms in the atmosphere when high-energy neutrons from secondary cosmic rays spall nitrogen and oxygen atoms
Summary
Concentrations of meteoric 10Be adhered to Paleolake Friis sediments are used to model a minimum age of paleolacustrine deposition. One way to achieve this prerequisite is if meteoric waters do not infiltrate the subsurface When these conditions are met, the measured 10Be reflects the initial inventory that was present at the time of burial, [10Be]initial, which is only altered by decay. We first determine a range of potential [10Be]initial. This is possible if we model lake sediments as soil surface sediments that have reached equilibrium between 10Be gain (via deposition) and loss (via erosion and decay). ~104 atoms g−1 indicates a lake sediment age of at least 14 My
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