Cosmic spherules from Widerøefjellet, Sør Rondane Mountains (East Antarctica)

A newly discovered sedimentary accumulation of micrometeorites in the Sør Rondane Mountains of East Antarctica, close to the Widerøefjellet summit at ∼2750 m above sea level, is characterized in this work. The focus here lies on 2099 melted cosmic spherules larger than 200 μm, extracted from 3.2 kg...

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Bibliographic Details
Published in:Geochimica et Cosmochimica Acta
Main Authors: Goderis, Steven, Soens, Bastien, Huber, Matthew S., McKibbin, Seann, van Ginneken, Matthias, Van Maldeghem, Flore, Debaille, Vinciane, Greenwood, Richard C., Franchi, Ian A., Cnudde, Veerle, Van Malderen, Stijn, Vanhaecke, Frank, Koeberl, Christian, Topa, Dan, Claeys, Philippe
Format: Article in Journal/Newspaper
Language:unknown
Published: Meteoritical Society 2020
Subjects:
QB651 Planets
Minor
QE515 Geochemistry
East Antarctica
Frontier Mountain
Miller Butte
Sør Rondane Mountains
Sør-Rondane
Transantarctic Mountains
Widerøefjellet
Antarc*
Antarctica
Online Access:https://kar.kent.ac.uk/88146/
https://doi.org/10.1016/j.gca.2019.11.016
Description
Summary:A newly discovered sedimentary accumulation of micrometeorites in the Sør Rondane Mountains of East Antarctica, close to the Widerøefjellet summit at ∼2750 m above sea level, is characterized in this work. The focus here lies on 2099 melted cosmic spherules larger than 200 μm, extracted from 3.2 kg of sampled sediment. Although the Widerøefjellet deposit shares similarities to the micrometeorite traps encountered in the Transantarctic Mountains, both subtle and more distinct differences in the physicochemical properties of the retrieved extraterrestrial particles and sedimentary host deposits are discernable (e.g., types of bedrock, degree of wind exposure, abundance of metal-rich particles). Unlike the Frontier Mountain and Miller Butte sedimentary traps, the size fraction below 240 μm indicates some degree of sorting at Widerøefjellet, potentially through the redistribution by wind, preferential alteration of smaller particles, or processing biases. However, the cosmic spherules larger than 300 μm appear largely unbiased following their size distribution, frequency by textural type, and bulk chemical compositions. Based on the available bedrock exposure ages for the Sør Rondane Mountains, extraterrestrial dust is estimated to have accumulated over a time span of ∼1–3 Ma at Widerøefjellet. Consequently, the Widerøefjellet collection reflects a substantial reservoir to sample the micrometeorite influx over this time interval. Petrographic observations and 3D microscopic CT imaging are combined with chemical and triple-oxygen isotopic analyses of silicate-rich cosmic spherules larger than 325 μm. The major element composition of 49 cosmic spherules confirms their principally chondritic parentage. For 18 glassy, 15 barred olivine, and 11 cryptocrystalline cosmic spherules, trace element concentrations are also reported on. Based on comparison with evaporation experiments reported in literature and accounting for siderophile and chalcophile element losses during high-density phase segregation and ejection, the ...

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