Magnetic and orbital ordering in cuprates and manganites
Abstract
The mechanisms of magnetic and orbital interactions due to double exchange (DE) and superexchange (SE) in transition metal oxides with degenerate eg orbitals are presented. Specifically, we study the effective spin-orbital models derived for the d9 ions as in KCuF3, and for the d4 ions as in LaMnO3, for spins S=1/2 and S=2, respectively. Such models are characterized by three types of elementary excitations: spin waves, orbital waves, and spin-and-orbital waves. The SE interactions between Cu2+ (d9) ions are inherently frustrated, which leads to a new mechanism of spin liquid which operates in three dimensions. The SE between Mn3+ (d4) ions explains the A-type antiferromagnetic order in LaMnO3 which coexists with the orbital order. In contrast, the ferromagnetic metallic phase and isotropic spin waves observed in doped manganites are explained by DE for degenerate eg orbitals. It is shown that although a hole does not couple to spin excitations in ferromagnetic planes of LaMnO3, the orbital excitations change the energy scale for the coherent hole propagation and cause a large redistribution of spectral weight. Finally, we point out some open problems in the present understanding of doped manganites.
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