Silicate Earth's missing niobium may have been sequestered into asteroidal cores

Autor(en)
Carsten Muenker, Raul O. C. Fonseca, Toni Schulz
Abstrakt

Geochemical models describing the behaviour of niobium during Earth’s growth rely on the general paradigm that niobium was delivered by Earth’s asteroidal building blocks at chondritic abundances. This paradigm is based on the observation that niobium is traditionally regarded as a refractory and strongly lithophile element, and thus stored in the silicate portions of Earth and differentiated asteroids. However, Earth’s silicate mantle is instead selectively depleted in niobium, in marked contrast to the silicate mantles of many asteroids and smaller planets that apparently lack any significant depletion in niobium. Here we present results of high-precision measurements for niobium and other lithophile elements in representative meteorites from various small differentiated asteroids. Our data, along with the results of low-pressure experiments, show that in more reduced asteroids—such as Earth’s first building blocks—niobium is moderately chalcophile and more so than its geochemical twin tantalum by an order of magnitude. Accordingly, niobium can be sequestered into the cores of more reduced asteroids during differentiation via the segregation of sulfide melts in a carbon-saturated environment. We suggest that the niobium deficit in Earth’s silicate mantle may be explained by the Earth’s silicate mantle preferentially accreting the silicate portions of reduced asteroidal building blocks.

Organisation(en)
Department für Lithosphärenforschung
Externe Organisation(en)
Universität zu Köln, Rheinische Friedrich-Wilhelms-Universität Bonn
Journal
Nature Geoscience
Band
10
Seiten
822-826
Anzahl der Seiten
5
ISSN
1752-0894
DOI
https://doi.org/10.1038/ngeo3048
Publikationsdatum
2017
Peer-reviewed
Ja
ÖFOS 2012
105105 Geochemie
ASJC Scopus Sachgebiete
Allgemeine Erdkunde und Planetologie
Link zum Portal
https://ucrisportal.univie.ac.at/de/publications/e87e63b7-5ae9-4516-8aaf-70b42a010906