The Formation of Magnesite Ores by Reactivation of Dunite Channels as a Key to Their Spatial Association to Chromite Ores in Ophiolites: An Example from Northern Evia, Greece

Giovanni Grieco; Alessandro Cavallo; Pietro Marescotti; Laura Crispini; Evangelos Tzamos; Micol Bussolesi

doi:10.3390/min13020159

Minerals (Jan 2023)

The Formation of Magnesite Ores by Reactivation of Dunite Channels as a Key to Their Spatial Association to Chromite Ores in Ophiolites: An Example from Northern Evia, Greece

Giovanni Grieco,
Alessandro Cavallo,
Pietro Marescotti,
Laura Crispini,
Evangelos Tzamos,
Micol Bussolesi

Affiliations

Giovanni Grieco: Department of Earth Sciences, University of Milan, Via Botticelli 23, 20122 Milan, Italy
Alessandro Cavallo: Department of Earth and Environmental Sciences—DISAT, University of Milan-Bicocca, P.zza della Scienza 1-4, 20126 Milan, Italy
Pietro Marescotti: Department of Earth Environment and Life Sciences—DISTAV, University of Genoa, Corso Europa 26, 16126 Genoa, Italy
Laura Crispini: Department of Earth Environment and Life Sciences—DISTAV, University of Genoa, Corso Europa 26, 16126 Genoa, Italy
Evangelos Tzamos: Ecoresources PC, Giannitson and Santarosa Str. 15-17, 54627 Thessaloniki, Greece
Micol Bussolesi: Department of Earth and Environmental Sciences—DISAT, University of Milan-Bicocca, P.zza della Scienza 1-4, 20126 Milan, Italy

DOI: https://doi.org/10.3390/min13020159
Journal volume & issue: Vol. 13, no. 2
p. 159

Abstract

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Ophiolite magnesite deposits are among the main sources of magnesite, a raw material critical for the EU. The present work focuses on magnesite occurrences at Kymasi (Evia Island, Greece), in close spatial association with chromitite within the same peridotite massif, and on the relationship between ultramafic rocks and late magnesite veins. Chromitite lenses are hosted within dunite, in contact with a partially serpentinized peridotite cut by magnesite veins. Close to the veins, the peridotite shows evidence of carbonation (forming dolomitized peridotite) and brecciation (forming a serpentinite–magnesite hydraulic breccia, in contact with the magnesite veins). Spinel mineral chemistry proved to be crucial for understanding the relationships between different lithologies. Spinels within partially serpentinized peridotite (Cr# 0.55–0.62) are similar to spinels within dolomitized peridotite (Cr# 0.58–0.66). Spinels within serpentinite–magnesite hydraulic breccia (Cr# 0.83–0.86) are comparable to spinels within dunite and chromitite (Cr# 0.79–0.84). This suggests that older weak zones, such as dunite channels, were reactivated as fluid pathways for the precipitation of magnesite. Magnesite stable isotope composition, moreover, points towards a meteoric origin of the oxygen, and to an organic source of carbon. The acquired data suggest the following evolution of Kymasi ultramafic rocks: (i) percolation of Cr-bearing melts in a supra-subduction mantle wedge within dunite channels; (ii) obduction of the ophiolitic sequence and peridotite serpentinization; (iii) uplift and erosion of mantle rocks to a shallow crustal level; (iv) percolation of carbon-rich meteoric waters rich at shallow depth, reactivating the dunite channels as preferential weak zones; and (v) precipitation of magnesite in veins and partial brecciation and carbonation of the peridotite host rock.

Published in Minerals

ISSN: 2075-163X (Online)
Publisher: MDPI AG
Country of publisher: Switzerland
LCC subjects: Science: Geology: Mineralogy
Website: https://www.mdpi.com/journal/minerals

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