Related papers: Stable computation of entanglement entropy for 2D interacting fermion systems

Stable computation of entanglement entropy for 2D interacting fermion systems

URL: http://arxiv.org/abs/2303.14326v3
Date: Tue, 29 Aug 2023 02:27:44 GMT
Title: Stable computation of entanglement entropy for 2D interacting fermion systems
Authors: Gaopei Pan, Yuan Da Liao, Weilun Jiang, Jonathan D'Emidio, Yang Qi and Zi Yang Meng
Abstract summary: entanglement entropy (EE) can be used to infer the organizing principle of 2D interacting fermion systems. EE has not been succeeded with reliable data that the universal scaling regime can be accessed. We show how to overcome the conceptual and computational barrier with the incremental algorithm.
Score: 1.3165428727965363
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: There is no doubt that the information hidden in entanglement entropy (EE), for example, the $n$-th order R\'enyi EE, i.e., $S^{A}_n=\frac{1}{1-n}\ln \Tr (\rho_A^n)$ where $\rho_A=\mathrm{Tr}_{\overline{A}}\rho$ is the reduced density matrix, can be used to infer the organizing principle of 2D interacting fermion systems, ranging from spontaneous symmetry breaking phases, quantum critical points to topologically ordered states. It is far from clear, however, whether the EE can actually be obtained with the precision required to observe these fundamental features -- usually in the form of universal finite size scaling behavior. Even for the prototypical 2D interacting fermion model -- the Hubbard model, to all existing numerical algorithms, the computation of the EE has not been succeeded with reliable data that the universal scaling regime can be accessed. Here we explain the reason for these unsuccessful attempts in EE computations in quantum Monte Carlo simulations in the past decades and more importantly, show how to overcome the conceptual and computational barrier with the incremental algorithm, such that the stable computation of the EE in 2D interacting fermion systems can be achieved and universal scaling information can be extracted. Relevance towards the experimental 2D interacting fermion systems is discussed.

Related papers

Imaginary-time evolution of interacting spin systems in the truncated Wigner approximation [0.0]
We extend the recently developed truncated Wigner approximation for spins to the imaginary time, termed iTWA.<n>Truncation at the Fokker-Planck level leads to a set of differential equations, which can be efficiently simulated.<n>We show that the iTWA can provide very good approximations to the ground state of a random and in general frustrated anti-ferromagnetic Ising Hamiltonian on a 3-regular graph.
arXiv Detail & Related papers (2026-03-04T11:22:09Z)
Emergent Distance from Mutual Information in the Critical 1D XXZ Spin Chain [0.0]
We numerically test a candidate distance metric in 1D, d_E, defined purely from quantum mutual information (I)<n>Our simulations show that in the quantum critical phase at anisotropy $Delta = 1.0$, the mutual information exhibits a power-law decay consistent with the emergence of a valid metric space.
arXiv Detail & Related papers (2025-07-13T19:00:06Z)
High-efficiency quantum Monte Carlo algorithm for extracting entanglement entropy in interacting fermion systems [4.758738320755899]
We propose a fermionic quantum Monte Carlo algorithm based on the incremental technique along physical parameters. We show the effectiveness of the algorithm and show the high precision. In this simulation, the calculated scaling behavior of the entanglement entropy elucidates the different phases of the Fermi surface and Goldstone modes.
arXiv Detail & Related papers (2024-09-30T07:07:51Z)
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)
KPZ scaling from the Krylov space [83.88591755871734]
Recently, a superdiffusion exhibiting the Kardar-Parisi-Zhang scaling in late-time correlators and autocorrelators has been reported. Inspired by these results, we explore the KPZ scaling in correlation functions using their realization in the Krylov operator basis.
arXiv Detail & Related papers (2024-06-04T20:57:59Z)
First-Order Phase Transition of the Schwinger Model with a Quantum Computer [0.0]
We explore the first-order phase transition in the lattice Schwinger model in the presence of a topological $theta$-term. We show that the electric field density and particle number, observables which reveal the phase structure of the model, can be reliably obtained from the quantum hardware.
arXiv Detail & Related papers (2023-12-20T08:27:49Z)
Universal features of entanglement entropy in the honeycomb Hubbard model [44.99833362998488]
This paper introduces a new method to compute the R'enyi entanglement entropy in auxiliary-field quantum Monte Carlo simulations. We demonstrate the efficiency of this method by extracting, for the first time, universal subleading logarithmic terms in a two dimensional model of interacting fermions.
arXiv Detail & Related papers (2022-11-08T15:52:16Z)
Entanglement dynamics of thermofield double states in integrable models [0.0]
We study the entanglement dynamics of thermofield double (TFD) states in integrable spin chains and quantum field theories. We show that, for a natural choice of the Hamiltonian eigenbasis, the TFD evolution may be interpreted as a quantum quench from an initial state. We conjecture a formula for the entanglement dynamics, which is valid for both discrete and continuous integrable field theories.
arXiv Detail & Related papers (2021-12-03T16:40:36Z)
Computing molecular excited states on a D-Wave quantum annealer [52.5289706853773]
We demonstrate the use of a D-Wave quantum annealer for the calculation of excited electronic states of molecular systems. These simulations play an important role in a number of areas, such as photovoltaics, semiconductor technology and nanoscience.
arXiv Detail & Related papers (2021-07-01T01:02:17Z)
Entanglement Entropy of Non-Hermitian Free Fermions [59.54862183456067]
We study the entanglement properties of non-Hermitian free fermionic models with translation symmetry. Our results show that the entanglement entropy has a logarithmic correction to the area law in both one-dimensional and two-dimensional systems.
arXiv Detail & Related papers (2021-05-20T14:46:09Z)
Quantum Simulation of Molecules without Fermionic Encoding of the Wave Function [62.997667081978825]
fermionic encoding of the wave function can be bypassed, leading to more efficient quantum computations. An application to computing the ground-state energy and 2-RDM of H$_4$ is presented.
arXiv Detail & Related papers (2021-01-27T18:57:11Z)
Eigenstate entanglement scaling for critical interacting spin chains [0.0]
Bipartite entanglement entropies of energy eigenstates cross over from the groundstate scaling to a volume law. We analyze XXZ and transverse-field Ising models with and without next-nearest-neighbor interactions.
arXiv Detail & Related papers (2020-10-14T17:44:54Z)
Attenuating the fermion sign problem in path integral Monte Carlo simulations using the Bogoliubov inequality and thermodynamic integration [0.0]
Accurate thermodynamic simulations of correlated fermions using path integral Monte Carlo (PIMC) methods are of paramount importance. The main obstacle is the fermion sign problem (FSP), which leads to an exponential increase in time. In the present work, we extend this approach by adding a parameter that controls the computation, allowing for an extrapolation to the exact result.
arXiv Detail & Related papers (2020-09-23T10:14:46Z)
Probing eigenstate thermalization in quantum simulators via fluctuation-dissipation relations [77.34726150561087]
The eigenstate thermalization hypothesis (ETH) offers a universal mechanism for the approach to equilibrium of closed quantum many-body systems. Here, we propose a theory-independent route to probe the full ETH in quantum simulators by observing the emergence of fluctuation-dissipation relations. Our work presents a theory-independent way to characterize thermalization in quantum simulators and paves the way to quantum simulate condensed matter pump-probe experiments.
arXiv Detail & Related papers (2020-07-20T18:00:02Z)

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