Semi-supervised learning of order parameter in 2D Ising and XY models using Conditional Variational Autoencoders

TL;DR

This paper demonstrates that conditional variational autoencoders can effectively learn and identify phase transitions and order parameters in 2D Ising and XY models using semi-supervised deep learning, without prior phase knowledge.

Contribution

It introduces a novel application of conditional variational autoencoders for semi-supervised phase detection in condensed matter models, improving correlation with known order parameters.

Findings

Latent parameters correlate with magnetization in Ising model.

The method accurately identifies critical temperatures.

It separates phases in XY model effectively.

Abstract

We investigate the application of deep learning techniques employing the conditional variational autoencoders for semi-supervised learning of latent parameters to describe phase transition in the two-dimensional (2D) ferromagnetic Ising model and the two-dimensional XY model. For both models, we utilize spin configurations generated using the Wolff algorithms below and above the critical temperatures. For the 2D Ising model we find the latent parameter of conditional variational autoencoders is correlated to the known order parameter of magnetization more efficiently than their correspondence in variational autoencoders used previously. It can also clearly identify the restoration of the $\mathbb{Z}_2$ symmetry beyond the critical point. The critical temperature extracted from the latent parameter at larger lattices are found to be approaching its correct value. Similarly, for the 2D XY model, we find our chosen network with the latent representation of conditional variational autoencoders is equally capable of separating the two phases between the high and low temperatures, again at the correct critical temperature with reasonable accuracy. Together these results show that the latent representation of conditional variational autoencoders can be employed efficiently to identify the phases of condensed matter systems, without their prior knowledge.