Significance of Secondary Fe-Oxide and Fe-Sulfide Minerals in Upper Peak Ring Suevite from the Chicxulub Impact Structure

Authors

Christina M. Verhagen, Rutgers University–New Brunswick
Ji In Jung, Stanford University
Sonia M. Tikoo, Stanford University
Axel Wittmann, Arizona State University
David A. Kring, Lunar and Planetary Institute
Stefanie Brachfeld, Montclair State UniversityFollow
Laying Wu, Montclair State UniversityFollow
Dale H. Burns, Stanford University
Sean P.S. Gulick, Jackson School of Geosciences

Document Type

Article

Publication Date

3-1-2023

Journal / Book Title

Minerals

Abstract

The suevite (polymict melt rock-bearing breccia) composing the upper peak ring of the Chicxulub impact crater is extremely heterogeneous, containing a combination of relict clasts and secondary minerals. Using scanning electron microscopy coupled with energy-dispersive X-ray spectroscopy (SEM/EDS) and electron probe microanalysis (EPMA), we investigated the nature and occurrence of primary and secondary Fe-oxide and Fe-sulfide minerals to better understand hydrothermal trends such as mineral precipitation and dissolution, and to document the remobilization of Fe and associated siderophile elements within suevites. Large primary Fe-oxides (~20–100 µm) reveal decomposition and dissolution patterns, forming sub-micrometer to micrometer Fe-oxide phases. Secondary sub-micrometer Fe-oxide crystals are also visibly concentrated within clay. The occurrence of Fe-oxide crystals within clay suggests that these likely formed at temperatures ≤100 °C, near the formation temperature of smectite. The formation of Fe-oxide minerals on clay surfaces is of interest as it may form a micro-setting, where free electrons (from the oxidation of Fe²⁺) and the adsorption of simple organic molecules on the surface of clay could generate reactive conditions favorable to microbial communities. Primary and secondary Fe-sulfide minerals exhibiting a variety of morphologies are present within samples, representing different formation mechanisms. Secondary Fe-sulfide minerals occur within rims of clasts and vesicles and in fractures and voids. Some secondary Fe-sulfide grains are associated with Ni- and Co-rich phases, potentially reflecting the post-impact migration of siderophile elements within the suevite of the Chicxulub crater.

Comments

This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/ 4.0/)

DOI

10.3390/min13030353

Journal ISSN / Book ISBN

85152396344 (Scopus)

MSU Digital Commons Citation

Verhagen, Christina M.; Jung, Ji In; Tikoo, Sonia M.; Wittmann, Axel; Kring, David A.; Brachfeld, Stefanie; Wu, Laying; Burns, Dale H.; and Gulick, Sean P.S., "Significance of Secondary Fe-Oxide and Fe-Sulfide Minerals in Upper Peak Ring Suevite from the Chicxulub Impact Structure" (2023). Department of Earth and Environmental Studies Faculty Scholarship and Creative Works. 722.
https://digitalcommons.montclair.edu/earth-environ-studies-facpubs/722

Published Citation

Verhagen, C. M., Jung, J.-I., Tikoo, S. M., Wittmann, A., Kring, D. A., Brachfeld, S., Wu, L., Burns, D. H., & Gulick, S. P. S. (2023). Significance of Secondary Fe-Oxide and Fe-Sulfide Minerals in Upper Peak Ring Suevite from the Chicxulub Impact Structure. Minerals, 13(3), 353. https://doi.org/10.3390/min13030353