Symmetry breaking and competing valence bond states in the star lattice Heisenberg antiferromagnet

Abstract

We investigate the ground state phase diagram of the spin-1/2 antiferromagnetic Heisenberg model on the star lattice using infinite projected entangled pair states (iPEPS) and high-order series expansions. The model includes two distinct couplings: Jd on the dimer bonds and Jt on the trimer bonds. While it is established that the system hosts a valence bond solid (VBS) phase for Jd Jt, the ground state phase diagram for Jd < Jt has remained unsettled. Our iPEPS simulations uncover a first-order phase transition at Jd/Jt ≈ 0.18, significantly lower than previously reported estimates. Beyond this transition, we identify a close competition between two valence bond crystal (VBC) states: a columnar VBC and a 3 × 3 VBC, with the latter consistently exhibiting lower energy across all finite bond dimensions. The high-order series expansion supports this by finding that the 3 × 3 VBC state indeed becomes energetically favorable, but only at sixth order in perturbation theory, revealing the subtle nature of the competition between candidate states.