Competition between Neel, Haldane nematic, plaquette valence bond solid, and (π,π) valence bond solid phases in SU(N) analogs of S=1 square-lattice antiferromagnets

Abstract

We use stochastic series expansion (SSE) quantum Monte Carlo (QMC) methods to study the phases and transitions displayed by a class of sign-free designer Hamiltonians for SU(N) analogs of spin S=1 quantum antiferromagnets on the square lattice. The SU(N) spins are generators of the single-row two-column representation (complex conjugate of single-row two-column representation) on A (B) sublattices of the square lattice, and the Hamiltonian is designed to explore the competition between the nearest neighbour antiferromagnetic exchange couplings J and four-spin interactions Q that favor a plaquette-ordered valence bond solid (p-VBS) ground state. We find that this state is indeed established at large Q/J for all N > 3. For 3< N ≤ 9, the ground state exhibits a direct first order quantum phase transition from a small-Q/J N\'eel ordered antiferromagnetic state to this large-Q/J p-VBS state. The ground state at Q/J=0 for N ≥ 10 has been previously reported to be a valence bond nematic state, dubbed the Haldane nematic in recent literature. For small nonzero Q/J and N ≥ 10, we additionally find an unusual intermediate state in which the bond energy has a Bragg peak at wavevector (π,π) with no accompanying Bragg peaks at wavevectors (π,0) and (0, π). This (π, π) state also appears to be metastable at Q/J =0, as evidenced by low temperature histograms of the Haldane nematic and (π, π) order parameters. Deep in the p-VBS phase of the ground state phase diagram, we find the temperature-driven melting of the p-VBS order is in the Ashkin-Teller universality class. In this regime, we identify an interesting signature of Ashkin-Teller criticality in bond correlations at wavevector (π, π); this is in addition to the expected critical fluctuations of the conventional p-VBS order parameter at wavevectors (π,0) and (0,π).