Watch the Dallas Symposium LIVE, and fundraiser auction
Ticket proceeds support mindat.org! - click here...
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

Salvioli-Mariani, E., Toscani, L., Bersani, D. (2004) Magmatic evolution of the Gaussberg lamproite (Antarctica): volatile content and glass composition. Mineralogical Magazine, 68 (1) 83-100 doi:10.1180/0026461046810173

Advanced
   -   Only viewable:
Reference TypeJournal (article/letter/editorial)
TitleMagmatic evolution of the Gaussberg lamproite (Antarctica): volatile content and glass composition
JournalMineralogical Magazine
AuthorsSalvioli-Mariani, E.Author
Toscani, L.Author
Bersani, D.Author
Year2004 (February)Volume68
Issue1
PublisherMineralogical Society
DOIdoi:10.1180/0026461046810173Search in ResearchGate
Generate Citation Formats
Mindat Ref. ID243522Long-form Identifiermindat:1:5:243522:4
GUID0
Full ReferenceSalvioli-Mariani, E., Toscani, L., Bersani, D. (2004) Magmatic evolution of the Gaussberg lamproite (Antarctica): volatile content and glass composition. Mineralogical Magazine, 68 (1) 83-100 doi:10.1180/0026461046810173
Plain TextSalvioli-Mariani, E., Toscani, L., Bersani, D. (2004) Magmatic evolution of the Gaussberg lamproite (Antarctica): volatile content and glass composition. Mineralogical Magazine, 68 (1) 83-100 doi:10.1180/0026461046810173
Abstract/NotesAbstractThe lamproite of Gaussberg is an ultrapotassic rock where leucite, olivine and clinopyroxene microphenocrysts occur in a glass-rich groundmass, containing microliths of leucite, clinopyroxene, apatite, phlogopite and rare K-richterite.Abundant silicate melt inclusions occur in olivine, leucite and, rarely, in clinopyroxene microphenocrysts. Raman investigations on melt inclusions showed the presence of pure CO2 in the shrinkage bubbles. On the other hand, the glass of the groundmass is CO2-poor and contains up to 0.70 wt.% of dissolved H2O, as estimated by infrared spectra. It is inferred that CO2 was released at every stage of evolution of the lamproite magma (CO2-rich shrinkage bubbles), whereas H2O was retained for longer in the liquid. At Gaussberg, CO2 seems to have a major role at relatively high pressure where it favoured the crystallization of H2O-poor microphenocrysts; the uprise of the magma to the surface decreased the solubility of CO2 and caused a relative increase in water activity. As a consequence, phlogopite and K-richterite appeared in the groundmass.The glass composition of both the groundmass and melt inclusions suggests different evolutions for the residual liquids of the investigated samples. Sample G886 shows the typical evolution of a lamproite magma, where the residual liquid evolves toward peralkaline and Na-rich composition and crystallizes K-richterite in the latest stage. Sample G895 derives from mixing/mingling of different batches of magma; effectively glasses from melt inclusions in leucite and clinopyroxene are more alkaline than those found in early crystallized olivine. Leucite and clinopyroxene crystallized early from a relatively more alkaline batch of lamproite magma and, successively, a less alkaline, olivinebearing magma batch assimilated them during its rise to the surface.

See Also

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

Salvioli-Mariani, E., Toscani, L., Venturelli, G. (2001) Weathering of granodiorite and micaschists, and soil pollution at Mt. Mottarone (northern Italy) Mineralogical Magazine, 65 (3) 415-425 doi:10.1180/002646101300119493
Toscani, L., & Salvioli-Mariani, E. (2000). The lamproite of El Tale (Fortuna, Southeast Spain). Chemie der Erde, 60(2), 96-110.
Toscani, L. (1999) Magmatic gold grains in the El Tale lamproite, Fortuna, SE Spain. Mineralogical Magazine, 63 (4) 595-602 doi:10.1180/minmag.1999.063.4.12
Venturelli, Giampiero, Toscani, Lorenzo, Salvioli-Mariani, Emma, Capedri, Silvio (1991) Mixing between lamproitic and dacitic components in miocene volcanic rocks of S.E. Spain. Mineralogical Magazine, 55 (379) 282-285 doi:10.1180/minmag.1991.055.379.18
Salvioli-Mariani, E., Toscani, L., Bersani, D., Oddone, M., Cancelliere, R. (2012) Late veins of C3 carbonatite intrusion from Jacupiranga complex (Southern Brazil): fluid and melt inclusions and mineralogy. Mineralogy and Petrology, 104 (1) 95-114 doi:10.1007/s00710-011-0179-1
Salvioli-Mariani, E., Boschetti, T., Toscani, L., Montanini, A., Petriglieri, J. R., and Bersani, D. (2020) Multi-stage rodingitization of ophiolitic bodies from Northern Apennines (Italy): Constraints from petrography, geochemistry and thermodynamic modelling. Geoscience Frontiers, 11(6), 2103-2125.
Salvioli-Mariani, E., Toscani, L., Boschetti, T., Bersani, D., Mattioli, M. (2015) Gold mineralisations in the Canan area, Lepaguare District, east-central Honduras: Fluid inclusions and geochemical constraints on gold deposition. Journal of Geochemical Exploration, 158. 243-256 doi:10.1016/j.gexplo.2015.08.003
Venturelli, Giampiero, Capedri, Silvio, Barbieri, Mario, Toscani, Lorenzo, Salvioli Mariani, Emma, Zerbi, Marco (1991) The Jumilla lamproite revisited: a petrological oddity. European Journal of Mineralogy, 3 (1) 123-146 doi:10.1127/ejm/3/1/0123
Salvioli-Mariani, E., Renzulli, A., Serri, G., Holm, P.M., Toscani, L. (2005) Glass-bearing crustal xenoliths (buchites) erupted during the recent activity of Stromboli (Aeolian Islands) Lithos, 81 (1) 255-277 doi:10.1016/j.lithos.2004.12.001
Venturelli, G., Salvioli-Mariani, E., Toscani, L., Barbieri, M., Gorgoni, C. (1993) Post-magmatic apatite + hematite + carbonate assemblage in the Jumilla lamproites. A fluid inclusion and isotope study. Lithos, 30 (2) 139-150 doi:10.1016/0024-4937(93)90012-2
Venturelli, G., Salvioli-Mariani, E., Toscani, L., Barbieri, M., & Gorgoni, C. (1993). Post-magmatic apatite+ hematite+ carbonate assemblage in the Jumilla lamproites. A fluid inclusion and isotope study. Lithos, 30(2), 139-150. https://doi.org/10.1016/0024-4937(93)90012-2
 
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 Β© 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: August 17, 2025 07:40:41
Go to top of page