Ferromagnetism and Lattice Distortions in the Perovskite YTiO3

Abstract

The thermodynamic properties of the ferromagnetic perovskite YTiO3 are investigated by thermal expansion, magnetostriction, specific heat, and magnetization measurements. The low-temperature spin-wave contribution to the specific heat, as well as an Arrott plot of the magnetization in the vicinity of the Curie temperature TC27 K, are consistent with a three-dimensional Heisenberg model of ferromagnetism. However, a magnetic contribution to the thermal expansion persists well above TC, which contrasts with typical three-dimensional Heisenberg ferromagnets, as shown by a comparison with the corresponding model system EuS. The pressure dependences of TC and of the spontaneous moment Ms are extracted using thermodynamic relationships. They indicate that ferromagnetism is strengthened by uniaxial pressures p a and is weakened by uniaxial pressures p b,c and hydrostatic pressure. Our results show that the distortion along the a- and b-axes is further increased by the magnetic transition, confirming that ferromagnetism is favored by a large GdFeO3-type distortion. The c-axis results however do not fit into this simple picture, which may be explained by an additional magnetoelastic effect, possibly related to a Jahn-Teller distortion.