Vote for your favorite mineral in #MinCup25! - Baryte vs. Hematite
It's a heavyweight match between industrial powerhouses as soft #baryte competes against rusty red #hematite.
Log InRegister
Quick Links : The Mindat ManualThe Rock H. Currier Digital LibraryMindat Newsletter [Free Download]
Home PageAbout MindatThe Mindat ManualHistory of MindatCopyright StatusWho We AreContact UsAdvertise on Mindat
Donate to MindatCorporate SponsorshipSponsor a PageSponsored PagesMindat AdvertisersAdvertise on Mindat
Learning CenterWhat is a mineral?The most common minerals on earthInformation for EducatorsMindat ArticlesThe ElementsThe Rock H. Currier Digital LibraryGeologic Time
Minerals by PropertiesMinerals by ChemistryAdvanced Locality SearchRandom MineralRandom LocalitySearch by minIDLocalities Near MeSearch ArticlesSearch GlossaryMore Search Options
Search For:
Mineral Name:
Locality Name:
Keyword(s):
 
The Mindat ManualAdd a New PhotoRate PhotosLocality Edit ReportCoordinate Completion ReportAdd Glossary Item
Mining CompaniesStatisticsUsersMineral MuseumsClubs & OrganizationsMineral Shows & EventsThe Mindat DirectoryDevice SettingsThe Mineral Quiz
Photo SearchPhoto GalleriesSearch by ColorNew Photos TodayNew Photos YesterdayMembers' Photo GalleriesPast Photo of the Day GalleryPhotography

Geisler, T., Rashwan, A. A., Rahn, M. K. W., Poller, U., Zwingmann, H., Pidgeon, R. T., Schleicher, H., Tomaschek, F. (2003) Low-temperature hydrothermal alteration of natural metamict zircons from the Eastern Desert, Egypt. Mineralogical Magazine, 67 (3) 485-508 doi:10.1180/0026461036730112

Advanced
   -   Only viewable:
Reference TypeJournal (article/letter/editorial)
TitleLow-temperature hydrothermal alteration of natural metamict zircons from the Eastern Desert, Egypt
JournalMineralogical Magazine
AuthorsGeisler, T.Author
Rashwan, A. A.Author
Rahn, M. K. W.Author
Poller, U.Author
Zwingmann, H.Author
Pidgeon, R. T.Author
Schleicher, H.Author
Tomaschek, F.Author
Year2003 (June)Volume67
Issue3
PublisherMineralogical Society
DOIdoi:10.1180/0026461036730112Search in ResearchGate
Generate Citation Formats
Mindat Ref. ID243441Long-form Identifiermindat:1:5:243441:8
GUID0
Full ReferenceGeisler, T., Rashwan, A. A., Rahn, M. K. W., Poller, U., Zwingmann, H., Pidgeon, R. T., Schleicher, H., Tomaschek, F. (2003) Low-temperature hydrothermal alteration of natural metamict zircons from the Eastern Desert, Egypt. Mineralogical Magazine, 67 (3) 485-508 doi:10.1180/0026461036730112
Plain TextGeisler, T., Rashwan, A. A., Rahn, M. K. W., Poller, U., Zwingmann, H., Pidgeon, R. T., Schleicher, H., Tomaschek, F. (2003) Low-temperature hydrothermal alteration of natural metamict zircons from the Eastern Desert, Egypt. Mineralogical Magazine, 67 (3) 485-508 doi:10.1180/0026461036730112
Abstract/NotesAbstractThe chemical and structural alteration of metamict zircon crystals from a 619 ±17 (2σ) Ma old, posttectonic granite in the southern part of the Eastern Desert, Egypt was studied. The crystals show simple oscillatory growth zones with metamictization–induced fractures, which provided pathways for fluid infiltration. Electron and ion microprobe analyses reveal that metamict, i.e. U and Th–rich, areas are heavily enriched in Ca, Al, Fe, Mn, LREE, and a water species, and have lost Zr and Si as well as radiogenic Pb. These chemical changes are the result of an intensive reaction with a low–temperature (120—200°C) aqueous solution. The chemical reactions probably occurred within the amorphous regions of the metamict network. During the zircon–fluid interactions the metamict structure was partially recovered, as demonstrated by micro-Raman and -infrared measurements. A threshold degree of metamictization, as defined empirically by an α–decay dose, Dc, was necessary for zircons to undergo hydrothermal alteration. It is proposed that Dc marks the first percolation point, where the amorphous domains start to form percolating clusters in the metamict network and where bulk chemical diffusion is believed to increase dramatically. The time of the hydrothermal alteration is determined by a lower intercept age of a U-Pb SHRIMP discordia of 17.9 (2σ) Ma, which is in good agreement with an apatite fission track age of 22.2 (2σ) Ma. The hydrothermal alteration event occurred contemporaneously with the main rifting phase of the Red Sea and widespread low- temperature mineralizations along the Red Sea coast.

See Also

These are possibly similar items as determined by title/reference text matching only.

Geisler, Thorsten, Pidgeon, Robert T., Kurtz, Reinhardt, van Bronswijk, Wilhelm, Schleicher, Helmut (2003) Experimental hydrothermal alteration of partially metamict zircon. American Mineralogist, 88 (10) 1496-1513 doi:10.2138/am-2003-1013
Geisler, T., Berndt, J., Meyer, H.-W., Pollok, K., Putnis, A. (2004) Low-temperature aqueous alteration of crystalline pyrochlore: correspondence between nature and experiment. Mineralogical Magazine, 68 (6) 905-922 doi:10.1180/0026461046860230
Abdalla, H. M., Helba, H. A., Mohamed, F. H. (1998) Chemistry of columbite-tantalite minerals in rare metal granitoids, Eastern Desert, Egypt. Mineralogical Magazine, 62 (6) 821-836 doi:10.1180/002646198548197
Akçay, M., Özkan, H. M., Spiro, B., Wilson, R., Hoskin, P. W. O. (2003) Geochemistry of a high-T hydrothermal dolostone from the Emirli (Ödemiş, western Turkey) Sb-Au deposit. Mineralogical Magazine, 67 (4) 671-688 doi:10.1180/0026461036740126
Geisler, T., Pidgeon, R.T., van Bronswijk, W., Kurtz, R. (2002) Transport of uranium, thorium, and lead in metamict zircon under low-temperature hydrothermal conditions. Chemical Geology, 191 (1) 141-154 doi:10.1016/s0009-2541(02)00153-5
Geisler, Thorsten, Ulonska, Marcus, Schleicher, Helmut, Pidgeon, Robert T., van Bronswijk, Wilhelm (2001) Leaching and differential recrystallization of metamict zircon under experimental hydrothermal conditions. Contributions to Mineralogy and Petrology, 141 (1) 53-65 doi:10.1007/s004100000202
Jocelyn, J., Pidgeon, R. T. (1974) Examples of twinning and parallel growth in zircons from some Precambrian granites and gneisses. Mineralogical Magazine, 39 (305) 587-594 doi:10.1180/minmag.1974.039.305.13
Vance, E. R., Anderson, B. W. (1972) Study of metamict Ceylon zircons. Mineralogical Magazine, 38 (297) 605-613 doi:10.1180/minmag.1972.038.297.09
Kempe, U., Gruner, T., Renno, A. D., Wolf, D., René, M. (2004) Discussion on Wang et al. (2000) ‘Chemistry of Hf-rich zircons from the Laoshan I- and A-type granites, Eastern China’, Mineralogical Magazine, 64, 867–877. Mineralogical Magazine, 68 (4) 669-675 doi:10.1180/0026461046840211
Krause, W., Bernhardt, H.-J., Effenberger, H., Kolitsch, U., Lengauer, CH. (2003) Redefinition of arhbarite, Cu2Mg(AsO4)(OH)3. Mineralogical Magazine, 67 (5) 1099-1107 doi:10.1180/0026461036750145
Reynolds, L., Jones, T. P., Beérubeé, K. A., Wise, H., Richards, R. (2003) Toxicity of airborne dust generated by opencast coal mining. Mineralogical Magazine, 67 (2) 141-152 doi:10.1180/0026461036720091
 
and/or  
Mindat.org is an outreach project of the Hudson Institute of Mineralogy, a 501(c)(3) not-for-profit organization.
Copyright © mindat.org and the Hudson Institute of Mineralogy 1993-2025, except where stated. Most political location boundaries are © OpenStreetMap contributors. Mindat.org relies on the contributions of thousands of members and supporters. Founded in 2000 by Jolyon Ralph.
To cite: Ralph, J., Von Bargen, D., Martynov, P., Zhang, J., Que, X., Prabhu, A., Morrison, S. M., Li, W., Chen, W., & Ma, X. (2025). Mindat.org: The open access mineralogy database to accelerate data-intensive geoscience research. American Mineralogist, 110(6), 833–844. doi:10.2138/am-2024-9486.
Privacy Policy - Terms & Conditions - Contact Us / DMCA issues - Report a bug/vulnerability Current server date and time: September 19, 2025 01:53:09
Go to top of page