Electric and Magnetic Properties of Higher-Spin Kondo-Heisenberg Models at Strong Coupling

Abstract

We study higher-spin (S ≥ 1) generalization of the one-dimensional Kondo-Heisenberg model, in which the local spin-S moments of the Kondo lattice model interact with each other via the antiferromagnetic Heisenberg interaction (JH), by analytical and numerical methods. The strong-coupling (i.e., large Kondo-coupling) expansion maps out an insulating phase at half-filling whose magnetic correlation depends on the parity of 2S as well as a ferromagnetic metallic phase which dominates the strong-coupling region at generic fillings. Then, we carried out the Density-Matrix Renormalization Group (DMRG) simulations for S=1 to closely investigate the phase structure at large but finite Kondo coupling. At half-filling, the Kondo coupling and JH do not compete and the insulating spin-gapless phase is stable, while the competition of the two leads to a stepwise collapse of the strong-coupling ferromagnetism via an intervening dimerized insulating phase with power-law spin correlation at quarter-filling.