Classical model emerges in quantum entanglement: Quantum Monte Carlo study for an Ising-Heisenberg bilayer
Siying Wu, Xiaoxue Ran, Binbin Yin, Qifang Li, Bin-Bin Mao, Yan-Cheng Wang, Yan Zheng
Abstract
By developing a cluster sampling of the stochastic series expansion quantum Monte Carlo method, we investigate a spin-$\frac{1}{2}$ model on a bilayer square lattice with intralayer ferromagnetic (FM) Ising coupling and interlayer antiferromagnetic Heisenberg interaction. The continuous quantum phase transition which occurs at ${g}_{c}=3.045(2)$ between the FM Ising phase and the dimerized phase is studied via large-scale simulations. From analysis of the critical exponents we show that this phase transition belongs to the ($2+1$)-dimensional Ising universality class. In addition, the quantum entanglement is strong between the two layers, especially in the dimerized phase. The effective Hamiltonian of a single layer seems like a transverse-field Ising model. However, we found that the quantum entanglement Hamiltonian is a pure classical Ising model without any quantum fluctuations. Furthermore, we give a more general explanation about how a classical entanglement Hamiltonian emerges.