Computing critical exponents in 3D Ising model via pattern recognition/deep learning approach
Abstract
In this study, we computed three critical exponents () for the 3D Ising model with Metropolis Algorithm using Finite-Size Scaling Analysis on six cube length scales (L=20,30,40,60,80,90), and performed a supervised Deep Learning (DL) approach (3D Convolutional Neural Network or CNN) to train a neural network on specific conformations of spin states. We find one can effectively reduce the information in thermodynamic ensemble-averaged quantities vs. reduced temperature t (magnetization per spin , specific heat per spin , magnetic susceptibility per spin ) to \textit{six} latent classes. We also demonstrate our CNN on a subset of L=20 conformations and achieve a train/test accuracy of 0.92 and 0.6875, respectively. However, more work remains to be done to quantify the feasibility of computing critical exponents from the output class labels (binned ) from this approach and interpreting the results from DL models trained on systems in Condensed Matter Physics in general.
Cite
@article{arxiv.2411.02604,
title = {Computing critical exponents in 3D Ising model via pattern recognition/deep learning approach},
author = {Timothy A. Burt},
journal= {arXiv preprint arXiv:2411.02604},
year = {2024}
}