One-dimensional spin liquid, collinear, and spiral phases from uncoupled chains to the triangular lattice

Abstract

We investigate the Hubbard model on the anisotropic triangular lattice with two hopping parameters t and t in different spatial directions, interpolating between decoupled chains (t=0) and the isotropic triangular lattice (t=t). Variational wave functions that include both Jastrow and backflow terms are used to compare spin-liquid and magnetic phases with different pitch vectors describing both collinear and coplanar (spiral) order. For relatively large values of the on-site interaction U/t 10 and substantial frustration, i.e., 0.3 t/t 0.8, the spin-liquid state is clearly favored over magnetic states. Spiral magnetic order is only stable in the vicinity of the isotropic point, while collinear order is obtained in a wide range of inter-chain hoppings from small to intermediate frustration.