Recent computational studies of models for manganese oxides have revealed a rich phase diagram, which was not anticipated in early calculations in this context performed in the 1950s and 1960s. In particular, the transition between the antiferromagnetic insulator state of the hole-undoped limit and the ferromagnetic metal at finite hole density was found to occur through a mixed-phase process. When extended Coulomb interactions are included, a microscopically charged inhomogeneous state should be stabilized. These phase separation tendencies, also present at low electronic densities, influence the properties of the ferromagnetic region by increasing charge fluctuations. Experimental data reviewed here by applying several techniques for manganites and other materials are consistent with this scenario. Similarities with results previously discussed in the context of cuprates are clear from this analysis, although the phase segregation tendencies in manganites appear stronger.
The Kondo lattice Hamiltonian with ferromagnetic Hund's coupling as a model
for manganites is investigated. The classical limit for the spin of the
(localized) $t_{2g}$ electrons is analyzed on lattices of dimension 1,2,3 and
$\infty$ using several numerical methods. The phase diagram at low temperature
is presented. A regime is identified where phase separation occurs between hole
undoped antiferromagnetic and hole-rich ferromagnetic regions. Experimental
consequences of this novel regime are discussed. Regions of incommensurate spin
correlations have also been found. Estimations of the critical temperature in
3D are compatible with experiments.Comment: Accepted in Phys. Rev. Letter
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