Infinite projected entangled pair states simulations of the S = 1 bilinear-biquadratic Heisenberg model on the square lattice reveal an emergent Haldane phase in between the previously predicted antiferromagnetic and 3-sublattice 120 • magnetically ordered phases. This intermediate phase preserves SU(2) spin and translational symmetry but breaks lattice rotational symmetry, and it can be adiabatically connected to the Haldane phase of decoupled S = 1 chains. Our results contradict previous studies which found a direct transition between the two magnetically ordered states.The search for novel states of matter in quantum manybody systems is one of the most active areas in condensed matter physics. A fascinating example is the ground state of the S = 1 antiferromagnetic Heisenberg chain which, unlike the S = 1/2 chain, exhibits an energy gap, exponentially decaying spin-spin correlations, and gapless edge excitations in case of open boundaries. Thanks to Haldane's pioneering work and conjecture that such a gapped state emerges in integer Heisenberg spin chains in general [1,2], this phase has been named after him.The Haldane phase also extends to related S = 1 models, such as weakly-coupled S = 1 Heisenberg chains [3][4][5][6][7] which are realized in several quasi-1D materials [8][9][10][11][12][13], or the S = 1 bilinear-biquadratic Heisenberg (BBH) chain with Hamiltonian H = i,j cos(θ)S i · S j + sin(θ) (S i · S j ) 2 , for θ in between −π/4 and π/4. More recently, the Haldane phase has been understood as a simple example of a symmetry protected topological (SPT) phase [14][15][16][17].In the present work we focus on the BBH model in two dimensions, which has gained much interest in recent years [18][19][20][21][22][23][24][25][26]; firstly, due to its possible connection to the triangular lattice compounds NiGa 2 S 4 [27] and Ba 3 NiSb 2 O 9 [25, 28-30], and secondly, for θ = π/4, the model is equivalent to the SU(3) Heisenberg model which can be experimentally realized using ultra-cold fermionic atoms in optical lattices [31][32][33][34]. The latter has been shown to exhibit 3-sublattice order on the square and triangular lattices [35,36], and an important question concerns the stability of this phase away from the SU(3) symmetric point. Previous studies on the square lattice based on linear flavor-wave theory [24], exact diagonalization [24], and series expansion [26] predicted a direct transition between the AF and the 3-sublattice phase for θ ≈ 0.2π. However, the accurate study of this parameter regime remains very challenging because Quantum Monte Carlo suffers from the negative sign problem.In this paper we show, using state-of-the-art tensor network simulations, that in between the AF and the 3-
AF phaseHaldane phase 3-SL 120° phase 0.217(4) 0.189 (2) FIG. 1. Haldane phase emerging in between the antiferromagnetic (AF) and the 3-sublattice 120 • ordered phases.sublattice phase an intermediate quantum paramagnetic phase emerges which preserves translational and SU(2) spin symmetry, but breaks lattice rota...
