Universal Neel Temperature in Three-Dimensional Quantum Antiferromagnets

TL;DR

This paper demonstrates a universal relationship between the Ne9el temperature and the ground state staggered moment in three-dimensional quantum antiferromagnets, validated through quantum Monte Carlo simulations.

Contribution

It introduces a universal scaling relation between T_N and m_s in 3D quantum antiferromagnets, applicable across different dimerization patterns and useful for experimental analysis.

Findings

T_N is proportional to m_s near a quantum-critical point.

Universal scaling of T_N/T* versus m_s is observed.

The relation holds across different dimerization patterns.

Abstract

We study three-dimensional dimerized S=1/2 Heisenberg antiferromagnets, using quantum Monte Carlo simulations of systems with three different dimerization patterns. We propose a way to relate the N\'eel temperature T_N to the staggered moment m_s of the ground state. Mean-field arguments suggest that T_N is proportional to m_s close to a quantum-critical point. We find an almost perfect universality (including the prefactor) if T_N is normalized by a proper lattice-scale energy. We show that the temperature T* at which the magnetic susceptibility has a maximum is a good choise, i.e., T_N/T* versus m_s is a universal function (also beyond the linear regime). These results are useful for analyzing experiments on systems where the spin couplings are not known precisely, e.g., TlCuCl3.