The role of P2O5 in silicate melts

Phase equilibria data in the systems SiO₂-P₂O₅, P₂O₅-M_xO_y, and P₂O₅-M_xO_y-SiO₂ are employed in conjunction with Chromatographic and spectral data to investigate the role of P₂O₅ in silicate melts. Such data indicate that the behavior of P₂O₅ is complex. P₂O₅ depolymerizes pure SiO₂ melts by entering the network as a four-fold coordinated cation, but polymerizes melts in which an additional metal cation other than silicon is present. The effect of this polymerization is apparent in the widening of the granite-ferrobasalt two-liquid solvus. In this complex system P₂O₅ acts to increase phase separation by further enrichment of the high charge density cations Ti, Fe, Mg, Mn, Ca, in the ferrobasaltic liquid. P₂O₅ also produces an increase in the ferrobasalt-granite REE liquid distribution coefficients. These distribution coefficients are close to 4 in P₂O₅-free melts, but close to 15 in P₂O₅-bearing melts.The dual behavior of P₂O₅ is explained in a model which requires complexing of phosphate anions (analogous to silicate anions) and metal cations in the melt. This interaction destroys Si-O-M-O-Si bonds polymerizing the melt. The higher concentration of Si-O-M-O-Si bond complexes in immiscible ferrobasaltic liquids relative to their conjugate immiscible granite liquids explains the partitioning of P₂O₅ into the ferrobasaltic liquid.