Related papers: Generating function for projected entangled-pair states

Generating function for projected entangled-pair states

URL: http://arxiv.org/abs/2307.08083v2
Date: Mon, 4 Mar 2024 03:27:10 GMT
Title: Generating function for projected entangled-pair states
Authors: Wei-Lin Tu, Laurens Vanderstraeten, Norbert Schuch, Hyun-Yong Lee, Naoki Kawashima, Ji-Yao Chen
Abstract summary: We extend the generating function approach for tensor network diagrammatic summation. Taking the form of a one-particle excitation, we show that the excited state can be computed efficiently in the generating function formalism. We conclude with a discussion on generalizations to multi-particle excitations.
Score: 0.1759252234439348
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Diagrammatic summation is a common bottleneck in modern applications of projected entangled-pair states, especially in computing low-energy excitations of a two-dimensional quantum many-body system. To solve this problem, here we extend the generating function approach for tensor network diagrammatic summation, a scheme previously proposed in the context of matrix product states. Taking the form of a one-particle excitation, we show that the excited state can be computed efficiently in the generating function formalism, which can further be used in evaluating the dynamical structure factor of the system. Our benchmark results for the spin-$1/2$ transverse-field Ising model and Heisenberg model on the square lattice provide a desirable accuracy, showing good agreement with known results. We then study the spin-$1/2$ $J_1$-$J_2$ model on the same lattice and investigate the dynamical properties of the putative gapless spin liquid phase. We conclude with a discussion on generalizations to multi-particle excitations.

Related papers

Latent Space Energy-based Neural ODEs [73.01344439786524]
This paper introduces a novel family of deep dynamical models designed to represent continuous-time sequence data. We train the model using maximum likelihood estimation with Markov chain Monte Carlo. Experiments on oscillating systems, videos and real-world state sequences (MuJoCo) illustrate that ODEs with the learnable energy-based prior outperform existing counterparts.
arXiv Detail & Related papers (2024-09-05T18:14:22Z)
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)
Efficient and systematic calculation of arbitrary observables for the matrix product state excitation ansatz [0.0]
We present a method for calculating expectation values for excitations with a single-particle character in the thermodynamic limit. We demonstrate the versatility of our method by studying the low-lying excitations in the spin-1 Heisenberg chain and the one-dimensional Hubbard model. We hope that this technique will foster further advancements with the excitation ansatz.
arXiv Detail & Related papers (2024-08-30T08:59:29Z)
Spectroscopy of two-dimensional interacting lattice electrons using symmetry-aware neural backflow transformations [0.0]
We introduce a framework for embedding lattice symmetries in Neural Slater-Backflow-Jastrow wavefunction ansatzes. We demonstrate how our model allows us to target the ground state and low-lying excited states.
arXiv Detail & Related papers (2024-06-13T13:01:50Z)
Two-mode Squeezing in Floquet Engineered Power-law Interacting Spin Models [0.0]
We find scalable generation of entanglement in the form of two-mode squeezing between the layers can generically be achieved in powerlaw models. spatially-temporally engineered interactions allow to significantly increase the generated entanglement and in fact achieve Heisenberg limited scaling.
arXiv Detail & Related papers (2024-02-28T19:00:06Z)
Quantum tomography of helicity states for general scattering processes [55.2480439325792]
Quantum tomography has become an indispensable tool in order to compute the density matrix $rho$ of quantum systems in Physics. We present the theoretical framework for reconstructing the helicity quantum initial state of a general scattering process.
arXiv Detail & Related papers (2023-10-16T21:23:42Z)
Capturing dynamical correlations using implicit neural representations [85.66456606776552]
We develop an artificial intelligence framework which combines a neural network trained to mimic simulated data from a model Hamiltonian with automatic differentiation to recover unknown parameters from experimental data. In doing so, we illustrate the ability to build and train a differentiable model only once, which then can be applied in real-time to multi-dimensional scattering data.
arXiv Detail & Related papers (2023-04-08T07:55:36Z)
Dilute neutron star matter from neural-network quantum states [58.720142291102135]
Low-density neutron matter is characterized by the formation of Cooper pairs and the onset of superfluidity. We model this density regime by capitalizing on the expressivity of the hidden-nucleon neural-network quantum states combined with variational Monte Carlo and reconfiguration techniques.
arXiv Detail & Related papers (2022-12-08T17:55:25Z)
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)
Efficient variational contraction of two-dimensional tensor networks with a non-trivial unit cell [0.0]
tensor network states provide an efficient class of states that faithfully capture strongly correlated quantum models and systems. We generalize a recently proposed variational uniform matrix product state algorithm for capturing one-dimensional quantum lattices. A key property of the algorithm is a computational effort that scales linearly rather than exponentially in the size of the unit cell.
arXiv Detail & Related papers (2020-03-02T19:01:06Z)
Adiabatic ground state preparation in an expanding lattice [0.0]
We implement and characterize a numerical algorithm inspired by the $s$-source framework [Phys. Rev.B 93, 045127] for building a quantum many-body ground state wavefunction on a lattice of size $2L$. We find that the construction works particularly well when the gap is large and, interestingly, at scale in critical points.
arXiv Detail & Related papers (2020-02-22T01:18:48Z)

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