Flat-band Ferromagnetism of SU(N) Hubbard Model on the Kagome Lattices

Abstract

The kagome lattice, a well known example of the geometrically frustrated system, hosts a dispersionless flat band that offers a unique platform for studying correlation-driven quantum phenomena. At appropriate particle concentrations, the existence of a flat band allows a representation of percolation with nontrivial weights. In this work, we investigate the paramagnetic-ferromagnetic transition in the repulsive SU(N) Hubbard model on the kagome lattice within this percolation framework. In this representation, the model can be rigorously mapped to a classical N-state site-percolation problem on a triangular lattice, with the SU(N) symmetry reflected in the nontrivial weights. By large-scale Monte Carlo simulations for SU(3), SU(4), and SU(10) symmetries, we demonstrate that the critical particle concentration for ferromagnetism exceeds the standard percolation threshold and increases with N, indicating a strengthening of the effective entropic repulsion.