Extraordinary surface critical behavior induced by a topological dimer phase in a two-dimensional Heisenberg quantum magnet

Using quantum Monte Carlo simulations, we study the dimerized spin-1/2 Heisenberg model on a square lattice, focusing on the paramagnetic dimer phase and its edge states, and associated surface criticality behavior. The model can also be viewed as two-dimensional antiferromagnetically (AF) coupled usual ladders with AF rungs. We demonstrate that the dimer phase of the model, previously considered topologically trivial, is actually a quasi-one-dimensional (Q1D) Haldane phase belonging to a symmetry-protected topological (SPT) state. This is established by measuring generalized strange correlators introduced in this work and further confirmed by showing that the nontrivial edge state on a zigzag cut in the dimer phase is ferromagnetically ordered, resulting from effective ferromagnetic interactions between degenerate spinons generated on each side of the zigzag cut. Furthermore, we show that the ordered edge state gives rise to an extraordinary surface critical behavior at the (2+1)-dimensional O(3) bulk critical points of the model, which contradicts theoretical predictions based on classical-quantum mapping.