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- Title
Mineralogy and chemical aspects of some ophiolitic metaultramafics, central Eastern Desert, Egypt: Evidences from chromites, sulphides and gangues.
- Authors
Abdel‐Karim, Abdel‐Aal M.; El‐Shafei, Shaimaa A.
- Abstract
Chromites and sulphides are the most common ore minerals in the ophiolitic metasomatized ultramafics (~790 Ma) of Um Halham, Fawakhir and Barramiya, central Eastern Desert, Egypt. These ultramafics exhibit variable degrees of alteration and metasomatism and include massive serpentinites (serpentinized peridotite and serpentinite), tremolite‐talc rocks, talc‐carbonate rocks, listwaenite‐like rocks and typical listwaenite. The alteration of chromite to Cr‐magnetite was accompanied by the formation of chloritic aureoles due to the release of Al and Mg from chromite. Textural and compositional features of the chromites suggest a greenschist up to lower amphibolite facies metamorphism (at 500–600 °C), which is facial with the host ultramafics. The chromites exhibit a boninitic affinity and a forearc suprasubduction setting of the present ophiolite assemblages. The variability of chromite chemistry indicates a melt‐rock reaction, together with the water‐bearing melt which is necessary for crystallizing chromite. Pentlandite, pyrrhotite, arsenopyrite, gersdorffite and pyrite are the most common sulphide minerals. Gold occurs either as an invisible phase associated with gersdorffite, arsenopyrite, and As‐rich pyrite or as native nuggets in listwaenites of Barramiya area. Gangue metasomatized phases associated with these ore minerals are identified as sericite, carbonate and chlorite. The investigated sericite ranges in composition from mariposite (>0.5% Cr) to fuchsite (>1% Cr), which indicates typical listwaenites. Five varieties of carbonate minerals are identified; magnesite, breunnerite, dolomite, calcite and ankerite. The CO2‐rich fluids are released during progressive decarbonation reactions in carbonate‐bearing metasediments, whereas Ni and As‐rich fluids are attributed to nearby granitic intrusions affected on serpentinites and leached Ni and precious metals like gold forming As‐Ni‐rich fluids. These metasomatic fluids are thought to reflect a range of melts derived from a compositionally evolving source during subduction initiation in a forearc environment.
- Subjects
MINERALOGY; CHROMITE; METASOMATISM; SERPENTINITE; MINERALS
- Publication
Geological Journal, 2018, Vol 53, Issue 2, p580
- ISSN
0072-1050
- Publication type
Article
- DOI
10.1002/gj.2914