Magnetic Phase Transition of the Perovskite-Type Ti Oxides

15 July 2000

journal article
Published by Physical Society of Japan in Journal of the Physics Society Japan

Vol. 69 (7) , 1982-1985
https://doi.org/10.1143/jpsj.69.1982

Abstract

Properties and mechanism of the magnetic phase transition of the perovskite-type Ti oxides, which is driven by the Ti-O-Ti bond angle distortion, are studied theoretically by using the effective spin and pseudo-spin Hamiltonian with strong Coulomb repulsion. It is shown that the A-type antiferromagnetic(AFM(A)) to ferromagnetic(FM) phase transition occurs as the Ti-O-Ti bond angle is decreased. Through this phase transition, the orbital state is hardly changed so that the spin-exchange coupling along the c-axis changes nearly continuously from positive to negative and takes approximately zero at the phase boundary. The resultant strong two-dimensionality in the spin coupling causes a rapid suppression of the critical temperature as is observed experimentally.Comment: 9 pages, 5 figure

Keywords

All Related Versions

Version 1, 2000-04-24, ArXiv

This publication has 17 references indexed in Scilit:

Metal-insulator transitions
Reviews of Modern Physics, 1998
Transport and magnetic properties of a Mott-Hubbard system whose bandwidth and band filling are both controllable: $R_{1 - x} {Ca}_{x} {TiO}_{3 + y / 2}$
Physical Review B, 1997
Electronic structure and orbital ordering in perovskite-type 3dtransition-metal oxides studied by Hartree-Fock band-structure calculations
Physical Review B, 1996
Unrestricted Hartree-Fock study of transition-metal oxides: Spin and orbital ordering in perovskite-type lattice
Physical Review B, 1995
Optical spectra in (La,Y) ${TiO}_{3}$ : Variation of Mott-Hubbard gap features with change of electron correlation and band filling
Physical Review B, 1995
The rare earth-titanium (III) perovskite oxides—An isostructural series with a remarkable variation in physical properties
Journal of the Less Common Metals, 1985
The magnetic structures of LaTiO3 and CeTiO3
Journal of Magnetism and Magnetic Materials, 1983
Magnetic behavior in the series LaxY1−xTiO3
Journal of Solid State Chemistry, 1982
Crystal growth, electrical resistivity, and magnetic properties of lanthanum titanate and cerium titanate. Evidence for a metal-semiconductor transition
Inorganic Chemistry, 1981
Simplified LCAO Method for the Periodic Potential Problem
Physical Review B, 1954