Related papers: Calculating Renyi Entropies with Neural Autoregressive Quantum States

Calculating Renyi Entropies with Neural Autoregressive Quantum States

URL: http://arxiv.org/abs/2003.01358v2
Date: Fri, 18 Dec 2020 00:36:42 GMT
Title: Calculating Renyi Entropies with Neural Autoregressive Quantum States
Authors: Zhaoyou Wang, Emily J. Davis
Abstract summary: Entanglement entropy is essential metric for characterizing quantum many-body systems. We estimate Renyi entropies of autoregressive neural quantum states with up to N=256 spins using quantum Monte Carlo methods.
Score: 0.0
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Entanglement entropy is an essential metric for characterizing quantum many-body systems, but its numerical evaluation for neural network representations of quantum states has so far been inefficient and demonstrated only for the restricted Boltzmann machine architecture. Here, we estimate generalized Renyi entropies of autoregressive neural quantum states with up to N=256 spins using quantum Monte Carlo methods. A naive "direct sampling" approach performs well for low-order Renyi entropies but fails for larger orders when benchmarked on a 1D Heisenberg model. We therefore propose an improved "conditional sampling" method exploiting the autoregressive structure of the network ansatz, which outperforms direct sampling and facilitates calculations of higher-order Renyi entropies in both 1D and 2D Heisenberg models. Access to higher-order Renyi entropies allows for an approximation of the von Neumann entropy as well as extraction of the single copy entanglement. Both methods elucidate the potential of neural network quantum states in quantum Monte Carlo studies of entanglement entropy for many-body systems.

Related papers

Fourier Neural Operators for Learning Dynamics in Quantum Spin Systems [77.88054335119074]
We use FNOs to model the evolution of random quantum spin systems. We apply FNOs to a compact set of Hamiltonian observables instead of the entire $2n$ quantum wavefunction.
arXiv Detail & Related papers (2024-09-05T07:18:09Z)
Neural network approach to quasiparticle dispersions in doped antiferromagnets [0.0]
We study the ability of neural quantum states to represent the bosonic and fermionic $t-J$ model on different 1D and 2D lattices. We present a method to calculate dispersion relations from the neural network state representation.
arXiv Detail & Related papers (2023-10-12T17:59:33Z)
Quantum Neural Estimation of Entropies [20.12693323453867]
entropy measures quantify the amount of information and correlation present in a quantum system. We propose a variational quantum algorithm for estimating the von Neumann and R'enyi entropies, as well as the measured relative entropy and measured R'enyi relative entropy.
arXiv Detail & Related papers (2023-07-03T17:30:09Z)
The Expressivity of Classical and Quantum Neural Networks on Entanglement Entropy [0.3299672391663526]
Von Neumann entropy from R'enyi entropies is a challenging problem in quantum field theory. We propose a general framework to tackle this problem using classical and quantum neural networks with supervised learning. Our proposed methods can accurately predict the von Neumann and R'enyi entropies numerically.
arXiv Detail & Related papers (2023-05-01T18:00:01Z)
Universality of critical dynamics with finite entanglement [68.8204255655161]
We study how low-energy dynamics of quantum systems near criticality are modified by finite entanglement. Our result establishes the precise role played by entanglement in time-dependent critical phenomena.
arXiv Detail & Related papers (2023-01-23T19:23:54Z)
Towards Neural Variational Monte Carlo That Scales Linearly with System Size [67.09349921751341]
Quantum many-body problems are central to demystifying some exotic quantum phenomena, e.g., high-temperature superconductors. The combination of neural networks (NN) for representing quantum states, and the Variational Monte Carlo (VMC) algorithm, has been shown to be a promising method for solving such problems. We propose a NN architecture called Vector-Quantized Neural Quantum States (VQ-NQS) that utilizes vector-quantization techniques to leverage redundancies in the local-energy calculations of the VMC algorithm.
arXiv Detail & Related papers (2022-12-21T19:00:04Z)
Neural network enhanced measurement efficiency for molecular groundstates [63.36515347329037]
We adapt common neural network models to learn complex groundstate wavefunctions for several molecular qubit Hamiltonians. We find that using a neural network model provides a robust improvement over using single-copy measurement outcomes alone to reconstruct observables.
arXiv Detail & Related papers (2022-06-30T17:45:05Z)
Probing finite-temperature observables in quantum simulators of spin systems with short-time dynamics [62.997667081978825]
We show how finite-temperature observables can be obtained with an algorithm motivated from the Jarzynski equality. We show that a finite temperature phase transition in the long-range transverse field Ising model can be characterized in trapped ion quantum simulators.
arXiv Detail & Related papers (2022-06-03T18:00:02Z)
Algorithm for initializing a generalized fermionic Gaussian state on a quantum computer [0.0]
We present explicit expressions for the central piece of a variational method developed by Shi et al. We derive iterative analytical expressions for the evaluation of expectation values of products of fermionic creation and subroutine operators. We present a simple gradient-descent-based algorithm that can be used as an optimization in combination with imaginary time evolution.
arXiv Detail & Related papers (2021-05-27T10:31:45Z)
A Neural-Network Variational Quantum Algorithm for Many-Body Dynamics [15.435967947933404]
We propose a neural-network variational quantum algorithm to simulate the time evolution of quantum many-body systems. The proposed algorithm can be efficiently implemented in near-term quantum computers with low measurement cost.
arXiv Detail & Related papers (2020-08-31T02:54:09Z)
Variational Monte Carlo calculations of $\mathbf{A\leq 4}$ nuclei with an artificial neural-network correlator ansatz [62.997667081978825]
We introduce a neural-network quantum state ansatz to model the ground-state wave function of light nuclei. We compute the binding energies and point-nucleon densities of $Aleq 4$ nuclei as emerging from a leading-order pionless effective field theory Hamiltonian.
arXiv Detail & Related papers (2020-07-28T14:52:28Z)

This list is automatically generated from the titles and abstracts of the papers in this site.