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Autori principali: Wu, Ang-Kun, Kloss, Benedikt, Krinitsin, Wladislaw, Fishman, Matthew T., Pixley, J. H., Stoudenmire, E. M.
Natura: Preprint
Pubblicazione: 2022
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Accesso online:https://arxiv.org/abs/2212.09798
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author Wu, Ang-Kun
Kloss, Benedikt
Krinitsin, Wladislaw
Fishman, Matthew T.
Pixley, J. H.
Stoudenmire, E. M.
author_facet Wu, Ang-Kun
Kloss, Benedikt
Krinitsin, Wladislaw
Fishman, Matthew T.
Pixley, J. H.
Stoudenmire, E. M.
contents Tensor network quantum states are powerful tools for strongly correlated systems, tailored to capture local correlations such as in ground states with entanglement area laws. When applying tensor network states to interacting fermionic systems, a proper choice of the basis or orbitals can reduce the bond dimension of tensors and provide physically relevant orbitals. We introduce such a change of basis with unitary gates obtained from compressing fermionic Gaussian states into quantum circuits corresponding to various tensor networks. These circuits can reduce the ground state entanglement entropy and improve the performance of algorithms such as the density matrix renormalization group. We study the Anderson impurity model with one and two impurities to show the potential of the method for improving computational efficiency and interpreting impurity physics. Furthermore, fermionic Gaussian circuits can also suppress entanglement during the time evolution out of low-energy state. Last, we consider Gaussian multi-scale entanglement renormalization ansatz (GMERA) circuits which compress fermionic Gaussian states hierarchically. The emergent coarse-grained physical models from these GMERA circuits are studied in terms of their entanglement properties and suitability for performing time evolution.
format Preprint
id arxiv_https___arxiv_org_abs_2212_09798
institution arXiv
publishDate 2022
record_format arxiv
spellingShingle Disentangling Interacting Systems with Fermionic Gaussian Circuits: Application to Quantum Impurity Models
Wu, Ang-Kun
Kloss, Benedikt
Krinitsin, Wladislaw
Fishman, Matthew T.
Pixley, J. H.
Stoudenmire, E. M.
Strongly Correlated Electrons
Quantum Physics
Tensor network quantum states are powerful tools for strongly correlated systems, tailored to capture local correlations such as in ground states with entanglement area laws. When applying tensor network states to interacting fermionic systems, a proper choice of the basis or orbitals can reduce the bond dimension of tensors and provide physically relevant orbitals. We introduce such a change of basis with unitary gates obtained from compressing fermionic Gaussian states into quantum circuits corresponding to various tensor networks. These circuits can reduce the ground state entanglement entropy and improve the performance of algorithms such as the density matrix renormalization group. We study the Anderson impurity model with one and two impurities to show the potential of the method for improving computational efficiency and interpreting impurity physics. Furthermore, fermionic Gaussian circuits can also suppress entanglement during the time evolution out of low-energy state. Last, we consider Gaussian multi-scale entanglement renormalization ansatz (GMERA) circuits which compress fermionic Gaussian states hierarchically. The emergent coarse-grained physical models from these GMERA circuits are studied in terms of their entanglement properties and suitability for performing time evolution.
title Disentangling Interacting Systems with Fermionic Gaussian Circuits: Application to Quantum Impurity Models
topic Strongly Correlated Electrons
Quantum Physics
url https://arxiv.org/abs/2212.09798