Trail, Dustin, Wang, Yanling (2018) Apatite stability under different oxygen fugacities relevant to planetary bodies. Mineralogy and Petrology, 112 (6) 789-800 doi:10.1007/s00710-018-0602-y
Reference Type | Journal (article/letter/editorial) | ||
---|---|---|---|
Title | Apatite stability under different oxygen fugacities relevant to planetary bodies | ||
Journal | Mineralogy and Petrology | ||
Authors | Trail, Dustin | Author | |
Wang, Yanling | Author | ||
Year | 2018 (December) | Volume | 112 |
Page(s) | 789-800 | Issue | 6 |
Publisher | Springer Science and Business Media LLC | ||
DOI | doi:10.1007/s00710-018-0602-ySearch in ResearchGate | ||
Mindat Ref. ID | 17561 | Long-form Identifier | mindat:1:5:17561:8 |
GUID | f69817ff-021d-408b-86de-88ad1712a5dc | ||
Full Reference | Trail, Dustin, Wang, Yanling (2018) Apatite stability under different oxygen fugacities relevant to planetary bodies. Mineralogy and Petrology, 112 (6) 789-800 doi:10.1007/s00710-018-0602-y | ||
Plain Text | Trail, Dustin, Wang, Yanling (2018) Apatite stability under different oxygen fugacities relevant to planetary bodies. Mineralogy and Petrology, 112 (6) 789-800 doi:10.1007/s00710-018-0602-y | ||
In | (2018, December) Mineralogy and Petrology Vol. 112 (6) Springer Science and Business Media LLC |
References Listed
These are the references the publisher has listed as being connected to the article. Please check the article itself for the full list of references which may differ. Not all references are currently linkable within the Digital Library.
Ayers JC, Watson EB (1991) Solubility of Apatite, Monazite, Zircon, and Rutile in Supercritical Aqueous Fluids with Implications for Subduction Zone Geochemistry. Philos T R Soc A 335(1638):365–375 | |
Dolejš D, Manning CE (2010) Thermodynamic model for mineral solubility in aqueous fluids: Theory, calibration and application to model fluid-flow systems. Geofluids 10:10–20 | |
Hughes JM, Rakovan J (2002) The Crystal Structure of Apatite, Ca5(PO4)3(F,OH,Cl). In: Kohn MJ, Rakovan J, Hughes JM (eds) Phosphates: Geochemical, geobiological, and materials importance. Rev Mineral Geochem, vol 48. Miner Soc Am, Washington DC, pp 1–12 | |
Marks, Michael A.W., Wenzel, Thomas, Whitehouse, Martin J., Loose, Matthias, Zack, Thomas, Barth, Matthias, Worgard, Linda, Krasz, Verena, Eby, G. Nelson, Stosnach, Hagen, Markl, Gregor (2012) The volatile inventory (F, Cl, Br, S, C) of magmatic apatite: An integrated analytical approach. Chemical Geology, 291. 241-255 doi:10.1016/j.chemgeo.2011.10.026 | |
McCubbin, Francis M., Jolliff, Bradley L., Nekvasil, Hanna, Carpenter, Paul K., Zeigler, Ryan A., Steele, Andrew, Elardo, Stephen M., Lindsley, Donald H. (2011) Fluorine and chlorine abundances in lunar apatite: Implications for heterogeneous distributions of magmatic volatiles in the lunar interior. Geochimica et Cosmochimica Acta, 75 (17) 5073-5093 doi:10.1016/j.gca.2011.06.017 | |
McCubbin, F. M., Shearer, C. K., Burger, P. V., Hauri, E. H., Wang, J., Elardo, S. M., Papike, J. J. (2014) Volatile abundances of coexisting merrillite and apatite in the martian meteorite Shergotty: Implications for merrillite in hydrous magmas. American Mineralogist, 99 (7) 1347-1354 doi:10.2138/am.2014.4782 | |
Newton RC, Manning CE (2010) Role of saline fluids in deep-crustal and upper-mantle metasomatism: Insights from experimental studies. Geofluids 10:58–72 | |
Piccoli PM, Candela PA (2002) Apatite in igneous systems. In: Kohn MJ, Rakovan J, Hughes JM (eds) Phosphates: Geochemical, geobiological, and materials importance. Rev Mineral Geochem, vol 48. Miner Soc Am, Washington DC, pp 255–292 | |
Ptáček, Petr, Opravil, Tomáš, Šoukal, František, Tkacz, Jakub, Másilko, Jiří, Bartoníčková, Eva (2016) The field of solid solutions in ternary system of synthetic apatite-type alkaline earth element-yttrium-silicate oxybritholite phases of the composition: AEE Y10−[SiO4]6O3−0.5, where AEE=Ca, Sr and Ba. Ceramics International, 42. 6154-6167 doi:10.1016/j.ceramint.2016.01.003 | |
Sato M, Hickling NL, McLane JE (1973) Oxygen fugacity values of Apollo 12 14 and 15 lunar samples and reduced state of lunar magmas. Proceedings of the Fourth Lunar Science Conference, Supplement 4. Geochim Cosmochim Ac 1:1061–1079 | |
Spear FS, Pyle JM (2002) Apatite, monazite, and xenotime in metamorphic rocks. In: Kohn MJ, Rakovan J, Hughes JM (eds) Phosphates: Geochemical, geobiological, and materials importance. Rev Mineral Geochem, vol 48. Miner Soc Am, Washington DC, pp 293–335 | |
Stormer JC, Pierson MI, Tacker RC (1993) Variation of F and CI X-ray intensity due to anisotropic diffusion in apatite during electron microprobe analysis. Am Mineral 78:641–648 | |
Watson EB (1987) Diffusion and solubility of C in Pt. Am Mineral 72:487–490 | |
Young EJ, Myers AT, Munson EL, Conklin NM (1969) Mineralogy and geochemistry of fluorapatite from Cerro De Mercado, Durango, Mexico. US Geol Surv Prof Pap 650-D:D84–D93 | |
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