P-T PSEUDOSECTION MODELING OF MINERAL ASSEMBLAGE STABILITY AND COMPOSITIONS FOR A MINERALOGICALLY SIMPLE PELITE: THE IMPORTANCE OF FINDING THE EFFECTIVE BULK COMPOSITION
Pseudosections constructed in the chemical system MnO-Na2O-CaO-K2O-FeO-MgO-Al2O3-SiO2-H2O-TiO2 (MnNCKFMASHT) with rock compositions determined by X-ray fluorescence analysis are used to compare predicted assemblage stability and phase compositions with those of the sample. Garnet stability is predicted, but not observed, at the conditions of metamorphism. Removal of MnO from the system does not resolve the discrepancy. However, removal of iron associated with pyrite yields the observed assemblage at the estimated P-T conditions of metamorphism (7-8 kilobars, 650 670 C).
The agreement between predicted phase compositions and measured phase compositions ranges from good to poor. Agreement between plagioclase compositions is good ( Ab83 vs. Ab82 observed). Predicted muscovite compositions contain too much paragonite (Pg) content ( Pg20 vs. Pg12 observed). Biotite compositions are fair (0.36 octahedral aluminum vs. 0.44 observed; 0.010 Mn atoms vs. 0.008 atoms observed; Fe/(Fe+Mg)=0.49 vs. 0.48 observed).
These results highlight the importance of using an effective bulk composition to model an individual sample. An average bulk composition from a suite of pelites from the Mica Creek region would not predict the proper assemblage for many pelites, and should not be used for deriving detailed P-T paths. However, adjusting rock compositions for the presence of phases not modeled and accounting for the effect of chemically zoned phases on rock composition allows accurate modeling in the MnNCKFMASHT system, although there are some problems with predicted white mica compositions.