Crossover from self-trapped bound states to perturbative scattering in the Heisenberg-Kondo lattice model
Abstract
We map out the complete transport phase diagram of the ferromagnetic Heisenberg-Kondo lattice model in two dimensions. The model involves tight-binding electrons with hopping t, coupled to classical spins with coupling J', while the spins have a nearest neighbour coupling J between them. We work with a fixed, small J/t, and study the temperature dependence of resistivity for varying electron density n and coupling J'/t. Our magnetic configurations are generated by exact diagonalisation-based Langevin dynamics, while the conductivity is computed using the Kubo formula on exact eigenstates. We work on lattices of size 20 × 20 and can access electron density down to n 0.01. The electron system remains homogeneous either when the mean density is large or when the coupling J' is small. In these situations, the resistivity (T) displays a monotonic increase with temperature and can be understood within a perturbative framework. However, at very low density n 0.05, strong coupling J'/t 1, and for T Tc, the electrons can locally polarise the magnetic state, create a trapping potential, and form a bound state in it. The resistivity associated with this polaronic phase is distinctly non-monotonic, with a peak near Tc. We establish the boundary that separates the many-body polaronic window from traditional scattering and extract a universal form for the resistivity in the scattering regime. We suggest the origin of the `excess resistivity' in the polaronic regime in terms of an increasing fraction of localised states as the temperature tends to Tc. This pushes the mobility edge towards the chemical potential μ and results in enhanced scattering of momentum states near kF. While our specific results are in two dimensions, the phenomenology we uncover should be valid even in three dimensions.
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