Related papers: Superposing and gauging fermionic Gaussian projected entangled pair states to get lattice gauge theory groundstates

Superposing and gauging fermionic Gaussian projected entangled pair states to get lattice gauge theory groundstates

URL: http://arxiv.org/abs/2412.01737v1
Date: Mon, 02 Dec 2024 17:31:20 GMT
Title: Superposing and gauging fermionic Gaussian projected entangled pair states to get lattice gauge theory groundstates
Authors: Gertian Roose, Erez Zohar,
Abstract summary: Gauged Gaussian fermionic projected entangled pair states (GGFPEPS) form a novel type of Ansatz state for the groundstate of lattice gauge theories. We will present a framework for the efficient computation of observables in the case where the non-Gaussianity of the PEPS follows from the superposition of (few) Gaussian PEPS.
Score: 0.0
License:
Abstract: Gauged Gaussian fermionic projected entangled pair states (GGFPEPS) form a novel type of Ansatz state for the groundstate of lattice gauge theories. The advantage of these states is that they allow efficient calculation of observables by combining Monte-Carlo integration over gauge fields configurations with Gaussian tensor network machinery for the fermionic part. Remarkably, for GGFPEPS the probability distribution for the gauge field configurations is positive definite and real so that there is no sign problem. In this work we will demonstrate that gauged (non-Gaussian) fermionic projected pair states (GFPEPS) exactly capture the groundstate of generic lattice gauge theories. Additionally, we will present a framework for the efficient computation of observables in the case where the non-Gaussianity of the PEPS follows from the superposition of (few) Gaussian PEPS. Finally, we present a new graphical notation for Gaussian tensor and their contractions into Gaussian tensor network states.

Related papers

Displaced Fermionic Gaussian States and their Classical Simulation [0.0]
This work explores displaced fermionic Gaussian operators with nonzero linear terms. We first demonstrate equivalence between several characterizations of displaced Gaussian states. We also provide an efficient classical simulation protocol for displaced Gaussian circuits.
arXiv Detail & Related papers (2024-11-27T17:05:04Z)
Gauged Gaussian PEPS -- A High Dimensional Tensor Network Formulation for Lattice Gauge Theories [0.0]
Gauge theories form the basis of our understanding of modern physics. In the non-perturbative regime, gauge theories are treated discretely as lattice gauge theories. We present a unified and comprehensive framework for gauged Gaussian Projected Entangled Pair States (PEPS)
arXiv Detail & Related papers (2024-04-19T18:14:43Z)
Gaussian Entanglement Measure: Applications to Multipartite Entanglement of Graph States and Bosonic Field Theory [50.24983453990065]
An entanglement measure based on the Fubini-Study metric has been recently introduced by Cocchiarella and co-workers. We present the Gaussian Entanglement Measure (GEM), a generalization of geometric entanglement measure for multimode Gaussian states. By providing a computable multipartite entanglement measure for systems with a large number of degrees of freedom, we show that our definition can be used to obtain insights into a free bosonic field theory.
arXiv Detail & Related papers (2024-01-31T15:50:50Z)
Finding the ground state of a lattice gauge theory with fermionic tensor networks: a $2+1d$ $\mathbb{Z}_2$ demonstration [0.0]
We use Gauged Gaussian Fermionic PEPS to find the ground state of $2+1d$ dimensional pure $mathbbZ$ lattice gauge theories. We do so by combining PEPS methods with Monte-Carlo computations, allowing for efficient contraction of the PEPS and computation of correlation functions.
arXiv Detail & Related papers (2022-10-31T18:00:02Z)
Projected d-wave superconducting state: a fermionic projected entangled pair state study [8.623262802078944]
We investigate the physics of projected d-wave pairing states using their fermionic projected entangled pair state (fPEPS) representation. Despite having very few variational parameters, such physically motivated tensor network states are shown to exhibit competitive energies for the doped t-J model.
arXiv Detail & Related papers (2022-08-09T07:06:11Z)
Conformal field theory from lattice fermions [77.34726150561087]
We provide a rigorous lattice approximation of conformal field theories given in terms of lattice fermions in 1+1-dimensions. We show how these results lead to explicit error estimates pertaining to the quantum simulation of conformal field theories.
arXiv Detail & Related papers (2021-07-29T08:54:07Z)
Dissipative evolution of quantum Gaussian states [68.8204255655161]
We derive a new model of dissipative time evolution based on unitary Lindblad operators. As we demonstrate, the considered evolution proves useful both as a description for random scattering and as a tool in dissipator engineering.
arXiv Detail & Related papers (2021-05-26T16:03:34Z)
Local optimization on pure Gaussian state manifolds [63.76263875368856]
We exploit insights into the geometry of bosonic and fermionic Gaussian states to develop an efficient local optimization algorithm. The method is based on notions of descent gradient attuned to the local geometry. We use the presented methods to collect numerical and analytical evidence for the conjecture that Gaussian purifications are sufficient to compute the entanglement of purification of arbitrary mixed Gaussian states.
arXiv Detail & Related papers (2020-09-24T18:00:36Z)
Efficient construction of tensor-network representations of many-body Gaussian states [59.94347858883343]
We present a procedure to construct tensor-network representations of many-body Gaussian states efficiently and with a controllable error. These states include the ground and thermal states of bosonic and fermionic quadratic Hamiltonians, which are essential in the study of quantum many-body systems.
arXiv Detail & Related papers (2020-08-12T11:30:23Z)
Variational Monte Carlo simulation with tensor networks of a pure $\mathbb{Z}_3$ gauge theory in (2+1)d [0.688204255655161]
Variational minimization of tensor network states enables the exploration of low energy states of lattice gauge theories. It is possible to efficiently compute physical observables using a variational Monte Carlo procedure. This is a first proof of principle to the method, which provides an inherent way to increase the number of variational parameters.
arXiv Detail & Related papers (2020-08-03T13:59:42Z)
Infinitely Wide Graph Convolutional Networks: Semi-supervised Learning via Gaussian Processes [144.6048446370369]
Graph convolutional neural networks(GCNs) have recently demonstrated promising results on graph-based semi-supervised classification. We propose a GP regression model via GCNs(GPGC) for graph-based semi-supervised learning. We conduct extensive experiments to evaluate GPGC and demonstrate that it outperforms other state-of-the-art methods.
arXiv Detail & Related papers (2020-02-26T10:02:32Z)

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