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Schneider, Jonathan B., Jenkins, David M. (2020) Stability of sodalite relative to nepheline in NaCl–H2O brines at 750 °C: Implications for hydrothermal formation of sodalite. The Canadian Mineralogist, 58 (1) 3-18 doi:10.3749/canmin.1900031

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Reference TypeJournal (article/letter/editorial)
TitleStability of sodalite relative to nepheline in NaCl–H2O brines at 750 °C: Implications for hydrothermal formation of sodalite
JournalThe Canadian Mineralogist
AuthorsSchneider, Jonathan B.Author
Jenkins, David M.Author
Year2020 (January 16)Volume58
Issue1
PublisherMineralogical Association of Canada
DOIdoi:10.3749/canmin.1900031Search in ResearchGate
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Mindat Ref. ID65640Long-form Identifiermindat:1:5:65640:5
GUID0
Full ReferenceSchneider, Jonathan B., Jenkins, David M. (2020) Stability of sodalite relative to nepheline in NaCl–H2O brines at 750 °C: Implications for hydrothermal formation of sodalite. The Canadian Mineralogist, 58 (1) 3-18 doi:10.3749/canmin.1900031
Plain TextSchneider, Jonathan B., Jenkins, David M. (2020) Stability of sodalite relative to nepheline in NaCl–H2O brines at 750 °C: Implications for hydrothermal formation of sodalite. The Canadian Mineralogist, 58 (1) 3-18 doi:10.3749/canmin.1900031
In(2020, January) The Canadian Mineralogist Vol. 58 (1) Mineralogical Association of Canada
Abstract/NotesABSTRACT
Formation of the feldspathoid sodalite (Na6Al6Si6O24·2NaCl) by reaction of nepheline (NaAlSiO4) with NaCl-bearing brines was investigated at 3 and 6 kbar and at a constant temperature of 750 °C to determine the brine concentration at which sodalite forms with variation in pressure. The reaction boundary was located by reaction-reversal experiments in the system NaAlSiO4–NaCl–H2O at a brine concentration of 0.16 ± 0.08 XNaCl [= molar ratio NaCl/(NaCl + H2O)] at 3 kbar and at a brine concentration of 0.35 ± 0.03 XNaCl at 6 kbar. Characterization of the sodalite using both X-ray diffraction and infrared spectroscopy after treatment in these brines indicated no obvious evidence of water or hydroxyl incorporation into the cage structure of sodalite. The data from this study were combined with earlier results by Wellman (1970) and Sharp et al. (1989) at lower (1–1.5 kbar) and higher (7–8 kbar) pressures, respectively, on sodalite formation from nepheline and NaCl which models as a concave-down curve in XNaCl – P space. In general, sodalite buffers the concentration of neutral aqueous NaCl° in the brine to relatively low values at P < 4 kbar, but NaCl° increases rapidly at higher pressures. Thermochemical modeling of these data was done to determine the activity of the aqueous NaCl° relative to a 1 molal (m) standard state, demonstrating very low activities (<0.2 m, or 1.2 wt.%) of NaCl° at 3 kbar and lower, but rising to relatively high activities (>20 m, or 54 wt.%) of NaCl° at 6 kbar or higher. The results from this study place constraints on the concentration of NaCl° in brines coexisting with nepheline and sodalite and, because of the relative insensitivity of this reaction to temperature, can provide a convenient geobarometer for those localities where the fluid compositions that formed nepheline and sodalite can be determined independently.

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