English

The Quantum Compass Model on the Square Lattice

Strongly Correlated Electrons 2009-11-11 v1

Abstract

Using exact diagonalizations, Green's function Monte Carlo simulations and high-order perturbation theory, we study the low-energy properties of the two-dimensional spin-1/2 compass model on the square lattice defined by the Hamiltonian H=r(Jxσrxσr+exx+Jzσrzσr+ezz)H = - \sum_{\bm{r}} (J_x \sigma_{\bm{r}}^x \sigma_{\bm{r} + \bm{e}_x}^x + J_z \sigma_{\bm{r}}^z \sigma_{\bm{r} + \bm{e}_z}^z). When JxJzJ_x\ne J_z, we show that, on clusters of dimension L×LL\times L, the low-energy spectrum consists of 2L2^L states which collapse onto each other exponentially fast with LL, a conclusion that remains true arbitrarily close to Jx=JzJ_x=J_z. At that point, we show that an even larger number of states collapse exponentially fast with LL onto the ground state, and we present numerical evidence that this number is precisely 2×2L2\times 2^L. We also extend the symmetry analysis of the model to arbitrary spins and show that the two-fold degeneracy of all eigenstates remains true for arbitrary half-integer spins but does not apply to integer spins, in which cases eigenstates are generically non degenerate, a result confirmed by exact diagonalizations in the spin-1 case. Implications for Mott insulators and Josephson junction arrays are briefly discussed.

Keywords

Cite

@article{arxiv.cond-mat/0501708,
  title  = {The Quantum Compass Model on the Square Lattice},
  author = {J. Dorier and F. Becca and F. Mila},
  journal= {arXiv preprint arXiv:cond-mat/0501708},
  year   = {2009}
}

Comments

8 pages, 8 figures