In situ synchrotron x-ray diffraction was conducted on polycrystalline DyPO4 to elucidate the details of the pressure-induced transition from the xenotime polymorph to the monazite polymorph. We used three different pressure-transmitting media (neon, a 16:3:1 methanol-ethanol-water mixture, and potassium chloride) to investigate the effect of hydrostaticity on the phase behavior. Specifically, our data clearly show a hydrostatic onset pressure of the xenotime-monazite transition of 9.1 GPa, considerably lower than the 15.3 GPa previously determined by Raman spectroscopy. Based on (quasi)hydrostatic data taken in a neon environment, third-order Birch-Murnaghan equation-of-state fits give a xenotime bulk modulus of 144 GPa and a monazite bulk modulus of 180 GPa (both with pressure derivatives of 4.0). Structural data and axial compressibilities show that DyPO4 is sensitive to shear and has an anisotropic response to pressure. More highly deviatoric conditions cause the onset of the transition to shift to pressures at least as low as 7.0 GPa. We attribute early transition to shear-induced distortion of the PO4 tetrahedra. Our characterization of the high-pressure behavior of DyPO 4 under variable hydrostaticity is critical for advancing rare earth orthophosphate fiber coating applications in ceramic matrix composites and may inform future tailoring of phase composition for controlled shear and pressure applications.

Sharma, Jai and Musselman, Matthew and Haberl, Bianca and Packard, Corinne E., In situ synchrotron diffraction of pressure-induced phase transition in DyPO4 under variable hydrostaticity, Phys. Rev. B, Vol. 103, Iss. 18 , abstract

[001] views of the (a) xenotime and (b) monazite phases of dysprosium orthophosphate DyPO4. Violet spheres represent Dy3+ cations, gray tetrahedra represent PO43 groups, and the boxes represent one unit cell. The apparent 90 ° rotation of monazite with respect to xenotime is merely a result of the monoclinic cell setting of monazite.