Central Limit Theorem of Overlap for the Mean Field Ghatak-Sherrington model

Abstract: The Ghatak-Sherrington (GS) spin glass model is a random probability measure defined on the configuration space ${0,\pm1,\pm2,\ldots, \pm \mathcal{S} }^N$ with system size $N$ and $\mathcal{S}\ge1$ finite. This generalizes the classical Sherrington-Kirkpatrick (SK) model on the boolean cube ${-1,+1}^N$ in order to capture more complex behaviors, including the spontaneous inverse freezing phenomenon. Although many results on the physics side have been established to understand the GS model, mathematical exploration of the model remains scarce. Overlap, the normalized inner product of two configurations, acts as the system order parameter to understand the phase transition of mean-field spin glass models. In this paper, we use moment method combined with the cavity approach to rigorously establish a quantitative joint central limit theorem for the overlap and self-overlap array. The results hold at high temperatures under arbitrary crystal and external fields. Compared to the SK model, the main challenge comes from the non-trivial self-overlap terms which also correlated with the standard overlap terms.