Related papers: Many-Body Neural Network Wavefunction for a Non-Hermitian Ising Chain

Many-Body Neural Network Wavefunction for a Non-Hermitian Ising Chain

URL: http://arxiv.org/abs/2506.11222v1
Date: Thu, 12 Jun 2025 18:42:41 GMT
Title: Many-Body Neural Network Wavefunction for a Non-Hermitian Ising Chain
Authors: Lavoisier Wah, Remmy Zen, Flore K. Kunst,
Abstract summary: Non-Hermitian (NH) quantum systems have emerged as a powerful framework for describing open quantum systems.<n>In this paper, we investigate the ground-state properties of a parity-time-symmetric, one-dimensional NH, transverse field Ising model with a complex spectrum.<n>We construct the NN-based many-body wavefunctions and validate our approach by recovering the ground-state properties of the model for small system sizes.
Score: 0.0
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Non-Hermitian (NH) quantum systems have emerged as a powerful framework for describing open quantum systems, non-equilibrium dynamics, and engineered quantum optical materials. However, solving the ground-state properties of NH systems is challenging due to the exponential scaling of the Hilbert space, and exotic phenomena such as the emergence of exceptional points. Another challenge arises from the limitations of traditional methods like exact diagonalization (ED). For the past decade, neural networks (NN) have shown promise in approximating many-body wavefunctions, yet their application to NH systems remains largely unexplored. In this paper, we explore different NN architectures to investigate the ground-state properties of a parity-time-symmetric, one-dimensional NH, transverse field Ising model with a complex spectrum by employing a recurrent neural network (RNN), a restricted Boltzmann machine (RBM), and a multilayer perceptron (MLP). We construct the NN-based many-body wavefunctions and validate our approach by recovering the ground-state properties of the model for small system sizes, finding excellent agreement with ED. Furthermore, for larger system sizes, we demonstrate that the RNN outperforms both the RBM and MLP. However, we show that the accuracy of the RBM and MLP can be significantly improved through transfer learning, allowing them to perform comparably to the RNN for larger system sizes. These results highlight the potential of neural network-based approaches--particularly for accurately capturing the low-energy physics of NH quantum systems.

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