Ambient temperature high-pressure-induced ferroelectric phase transition in CaMnTi2O6

Abstract

The ferroelectric to paraelectric phase transition of multiferroic CaMnTi2O6 has been investigated at high pressures and ambient temperature by second harmonic generation (SHG), Raman spectroscopy, and powder and single-crystal x-ray diffraction. We have found that CaMnTi2O6 undergoes a pressure-induced structural phase transition (P42mc → P42/nmc) at 7 GPa to the same paraelectric structure found at ambient pressure and Tc = 630 K. The continuous linear decrease of the SHG intensity that disappears at 7 GPa and the existence of a Raman active mode at 244 cm-1 that first softens up to 7 GPa and then hardens with pressure, are used to discuss the nature of the phase transition of CaMnTi2O6 for which a dTc/dP = -48 K/GPa has been found. Neither a volume contraction nor a change of the normalized pressure on the eulerian strain are observed across the phase transition with all the unit-cell volume data following a second order Birch-Murnaghan equation of state with a bulk modulus of B0 = 182.95(2) GPa.