Itinerant Ferromagnetism from One-Dimensional Mobility
Abstract
We propose a universal kinetic mechanism for a half-metallic ferromagnet -- a metallic state with full spin polarization -- arising from strong on-site Coulomb repulsions between particles that exhibit constrained one-dimensional (1D) dynamics. We illustrate the mechanism in the context of a solvable model on a Lieb lattice in which doped electrons have 1D mobility. Such 1D motion is shown to induce only multi-spin ring exchanges of even parity, which mediate ferromagnetism and result in a unique half-metallic ground state. In contrast to the Nagaoka mechanism of ferromagnetism, this result pertains to any doped electron density in the {\it thermodynamic} limit. We explore various microscopic routes to such (approximate) 1D dynamics, highlighting two examples: doped holes in the strong-coupling limit of the Emery model and vacancies in a two-dimensional Wigner crystal. Finally, we demonstrate an intriguing exact equivalence between the bosonic and fermionic versions of these models, which implies a novel mechanism for the conjectured Bose metallic phase.
Cite
@article{arxiv.2412.03638,
title = {Itinerant Ferromagnetism from One-Dimensional Mobility},
author = {Kyung-Su Kim and Veit Elser},
journal= {arXiv preprint arXiv:2412.03638},
year = {2025}
}
Comments
16 + 6 pages, 9 + 2 figures. Sec. V rewritten for clarity. Minor revisions otherwise