I-Type Cosmic Spherules as Proxy for the Δ′ 17 O of the Atmosphere—A Calibration With Quaternary Air

Remnants of shooting stars are preserved in form of cosmic spherules in ice and sediments. The extraterrestrial material is heated and melted upon atmospheric entry and is collected at the Earth's surface as cosmic spherules. A fraction of cosmic spherules (I-type cosmic spherules) sources from...

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Bibliographic Details
Published in:Paleoceanography and Paleoclimatology
Main Authors: Fischer, M., Oeser, M., Weyer, S., Folco, L., Peters, S., Zahnow, F., Pack, A.
Format: Article in Journal/Newspaper
Language:English
Published: 2021
Subjects:
Antarctic
Antarc*
Online Access:http://hdl.handle.net/21.11116/0000-0008-9BCB-5
Description
Summary:Remnants of shooting stars are preserved in form of cosmic spherules in ice and sediments. The extraterrestrial material is heated and melted upon atmospheric entry and is collected at the Earth's surface as cosmic spherules. A fraction of cosmic spherules (I-type cosmic spherules) sources from extraterrestrial Fe,Ni metal. These metal particles melt and become oxidized in the atmosphere. The oxygen in the resulting oxides (magnetite, wüstite) sources entirely from the atmosphere. Here, we demonstrate that I-type cosmic spherules can be used to reconstruct the triple oxygen isotope anomaly of the past atmosphere, which provides information on the gross primary productivity and/or paleo-CO 2 levels. We present a calibration of the proxy using Antarctic cosmic spherules. We further introduce Δ′ 56 Fe and demonstrate that triple iron isotopes can be used to obtain information about the underlying fractionation mechanism (e.g., kinetic vs. equilibrium fractionation).

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