Heisenberg models and a particular isotropic model

TL;DR

This paper analyzes the spectrum of Heisenberg models using group theory, revealing their structure and degeneracies, and applies these insights to a fully connected isotropic model to study finite size effects and phase transition behavior.

Contribution

It provides a group theoretical framework for understanding the spectrum of Heisenberg models and explicitly solves the isotropic fully connected case, highlighting finite size effects.

Findings

Spectrum decomposes into blocks labeled by total spin quantum numbers.

Partition function expressed as a single integral for the fully connected model.

Heat capacity shows notable behavior near the phase transition.

Abstract

The Heisenberg model, a quantum mechanical analogue of the Ising model, has a large ground state degeneracy, due to the symmetry generated by the total spin. This symmetry is also responsible for degeneracies in the rest of the spectrum. We discuss the global structure of the spectrum of Heisenberg models with arbitrary couplings, using group theoretical methods. The Hilbert space breaks up in blocks characterized by the quantum numbers of the total spin, $S$ and $M$, and each block is shown to constitute the representation space of an explicitly given irreducible representation of the symmetric group $S_N$, consisting of permutations of the $N$ spins in the system. In the second part of the paper we consider, as a concrete application, the model where each spin is coupled to all the other spins with equal strength. Its partition function is written as a single integral, elucidating its $N$-dependence. This provides a useful framework for studying finite size effects. We give explicit results for the heat capacity, revealing interesting behavior just around the phase transition.