Abstract
The partitioning of a large suite of trace elements between biotite and water-saturated granitic melt was measured at 2 kbar and 700—800 ˚C. To reach equilibrium and to grow biotite crystals large enough for analysis, runs usually lasted from 30 to 45 days. In every charge, a few trace elements were initially doped at the 0.1—0.5 wt. % level and analyzed by electron microprobe after the run. First-row transition metal ions are highly compatible in biotite with Dbiotite/melt of 17 for Ti, 35 for V, 47 for Co, 174 for Ni, and 5.8 for Zn. A very notable exception is Cu with Dbiotite/melt < 0.9. This is likely one of the reasons why Cu is enriched together with Mo (Dbiotite/melt = 0.29) in porphyry deposits associated with intermediate to felsic plutons, while the other transition metals are not. Both Nb and Ta are mildly compatible in biotite with Dbiotite/melt being larger for Nb (3.69) than for Ta (1.89). Moderate (15—30%) biotite fractionation would be sufficient to reduce the Nb/Ta ratio from the chondritic value to the range observed in the continental crust. Moreover, the strong partitioning of Ti into biotite implies that already modest biotite fractionation suppresses the saturation of Ti-oxide phases and thereby indirectly facilitates the enrichment of Ta over Nb in the residual melt. The heavy alkalis, alkaline earths, and Pb are only mildly fractionated between biotite and melt (Dbiotite/melt = 3.8 for Rb, 0.6 for Cs, 0.6 for Sr, 1.8 for Ba, 0.7 for Pb). The rare earth elements are generally incompatible in biotite, with a minimum for Dbiotite/melt of 0.03–0.06 at Gd, Tb, and Dy, while both the light and heavy rare earths are less incompatible (e.g. Dbiotite/melt = 0.6 for La and 0.3 for Yb). This behavior probably reflects a partitioning into two sites, the K site for the light rare earths and the octahedral Mg site for the heavy rare earths. There is no obvious dependence of the rare earth partition coefficients on tetrahedral Al in the biotite, presumably because charge balancing by cation vacancies is possible. Allanite was found as run product in some experiments. For the light rare earths, Dallanite/melt is very high (e.g. 385 to 963 for Ce and Nd) and appears to increase with decreasing temperatures. However, the rather high solubility of allanite in the melts implies that it likely only crystallizes during the last stages of cooling of most magmas, except if the source magma is unusually enriched in rare earths.
Highlights
Biotite K(Mg,Fe)3(OH)2AlSi3O10 is a sheet silicate and a common and abundant mineral in igneous rocks of intermediate to felsic composition, in plutonic environments (e.g. Speer 1984)
We have investigated the partitioning of a large suite of trace elements between biotite and granitic melts at 2 kbar and 700–800 ̊C under water-saturated conditions
The partition coefficients calculated from coexisting biotite and glass phase from the Bishop Tuff by Mahood & Hildreth (1983) are often remarkably similar to those measured in the current study, e.g. for Rb (4.3 versus 3.8 reported here), Cs (3.1 vs. 0.62), Ba (7 vs. 1.79), Ta (1.35 vs. 1.89), Cr (3.7 vs. 2.8), Co (86 vs. 47), and Zn (19 vs. 5.8)
Summary
Biotite K(Mg,Fe)3(OH)2AlSi3O10 is a sheet silicate and a common and abundant mineral in igneous rocks of intermediate to felsic composition, in plutonic environments (e.g. Speer 1984). It may accommodate various trace elements, either on the 12-coordinated K site (Bailey 1984) or on the octahedral Mg and Fe site. The partitioning of trace elements between biotite and felsic to intermediate melts is only poorly studied. A notable earlier experimental study is that of Icenhower and London (1995), who measured the partition coefficients of Li, Rb, Cs, Sr, Ba, and F between biotite and a peraluminous silicic melt, using a mixture of natural biotite with other minerals as starting material. Partition coefficients derived from the analysis of biotite phenocrysts and coexisting rhyolitic glass from natural volcanics were reported by Mahood and Hildreth (1983), Nash and Crecraft (1985), and by Ewart and Griffin (1994). Bea et al (1994) reported biotite/leucosome partition coefficients from a migmatite
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