Deep learning stochastic processes with QCD phase transition

It is nontrivial to recognize phase transitions and track dynamics inside a stochastic process because of its intrinsic stochasticity. In this paper, we employ the deep learning method to classify the phase orders and predict the damping coefficient of fluctuating systems under Langevin description....

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Bibliographic Details
Published in:Physical review. D 2021-06, Vol.103 (11), p.1, Article 116023
Main Authors: Jiang, Lijia, Wang, Lingxiao, Zhou, Kai
Format: Article
Language:English
Subjects:
Artificial neural networks
Classification
Configurations
Critical point
Damping
Deep learning
Neural networks
Order parameters
Phase transitions
Stochastic models
Stochastic processes
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Summary:It is nontrivial to recognize phase transitions and track dynamics inside a stochastic process because of its intrinsic stochasticity. In this paper, we employ the deep learning method to classify the phase orders and predict the damping coefficient of fluctuating systems under Langevin description. As a concrete setup, we demonstrate this paradigm for the scalar condensation in QCD matter near the critical point, in which the order parameter of the chiral phase transition can be characterized in a 1 + 1 -dimensional Langevin equation for the σ field. In a supervised learning manner, convolutional neural networks accurately classify the first-order phase transition and crossover based on σ field configurations with fluctuations. Noise in the stochastic process does not significantly hinder the performance of the well-trained neural network for phase order recognition. For mixed dynamics with diverse dynamical parameters, we further devise and train the machine to predict the damping coefficients η in a broad range. The results show that it is robust to extract the dynamics from the bumpy field configurations.
ISSN:2470-0010
2470-0029
DOI:10.1103/PhysRevD.103.116023