Elastic and nonlinear acoustic properties and thermal expansion of rare-earth metaphosphate glasses

Abstract

Abstract The thermal expansions and the ultrasonic wave velocities and attenuations of (Sm2O3)0.234(P2O5)0.776 and (La2O3)0.222 (P2O5)0.778 and mixed (La2O3)x (Sm2O3)y(P2O5)0.75 (where x + y = 0.25) metaphosphate glasses have been measured as functions of temperature. The change in the ultrasonic wave velocity induced by application of hydrostatic pressure up to 0.16 GPa has also been measured at selected temperatures between room temperature and 375 K. The experimental results provide the temperature dependences of the adiabatic elastic stiffnesses C11 and C44 and related elastic properties and provide the hydrostatic-pressure derivatives (∂C 11/∂P)P=0 and (∂C 44/∂P)p=0 of the elastic stiffnesses and (∂B S/∂P)P=0 of the bulk modulus. The results obtained for C IJ and (∂C IJ/∂P)P=0 are used to determine the long-wavelength acoustic-mode Grüneisen parameters; these quantify the vibrational anharmonicity, which is essential information for developing the acoustic mode contribution to the thermal expansion of the glasses. Hence the ultrasonic velocity measurements in metaphosphate glasses modified with Sm3+ and La3+ ions enable separation of these acoustic-mode contributions from those due to the excess modes. Using the soft-potential model, it has been shown that, at low temperatures, the excess low-energy vibrational states provide negative contributions to the thermal expansion and to the nonlinear acoustic properties. For the mixed metaphosphate glasses of the type (La2O3)x(Sm2O3)y(P2O5)0.75, the acoustic-mode softening induced by Sin3+ is negated by the addition of La3+; as a result the acoustic-mode Grüneisen parameters and the thermal expansion are extremely small.