Quantum Dimensional Transition in Spin-12 Antiferromagnetic Heisenberg Model on A Square Lattice and Space Reduction in Matrix Product State

Abstract

We study the spin-12 antiferromagnetic Heisenberg model on an infinity-by-N square lattice for even N's up to 14. Previously, the nonlinear sigma model perturbatively predicts that its spin rotational symmetry asymptotically breaks when N→ ∞, i.e., when it is two-dimensional (2D). However, we identified a critical width Nc = 10 for which this symmetry breaks spontaneously. It defines a dimensional transition from one-dimension (1D) including quasi-1D to 2D. The finite-size effect differs from that of the N-by-N lattice. The ground state (GS) energy per site approaches the thermodynamic limit value, in agreement with the previously accepted value, by one order of 1/N faster than when using N-by-N lattices in the literature. We build and variationally solve a matrix product state (MPS) on a chain, converting the N sites in the rung into an effective site. We show that the area law of entanglement entropy does not apply when N increases in our method, and show that the reduced density matrix of each effective site will have a saturating number of dominant diagonal elements with increasing N. These two characteristics make the MPS rank needed to obtain a demanded energy accuracy quickly saturate when N is large, making our algorithm efficient for large N's. And, the latter enables space reduction in MPS. Within the framework of MPS, we prove a theorem that the spin-spin correlation at infinite separation is the square of staggered magnetization and demonstrate that the eigenvalue structure of a building MPS unit of g g, g being the GS, is responsible for order, disorder and quasi-long-range order.