Quantum dynamics in transverse-field Ising models from classical networks

Schmitt, Markus; Heyl, Markus

doi:10.21468/SciPostPhys.4.2.013

SciPost Physics

Quantum dynamics in transverse-field Ising models from classical networks

Markus Schmitt, Markus Heyl

SciPost Phys. 4, 013 (2018) · published 28 February 2018

doi: 10.21468/SciPostPhys.4.2.013
pdf
Submissions/Reports

Abstract

The efficient representation of quantum many-body states with classical resources is a key challenge in quantum many-body theory. In this work we analytically construct classical networks for the description of the quantum dynamics in transverse-field Ising models that can be solved efficiently using Monte Carlo techniques. Our perturbative construction encodes time-evolved quantum states of spin-1/2 systems in a network of classical spins with local couplings and can be directly generalized to other spin systems and higher spins. Using this construction we compute the transient dynamics in one, two, and three dimensions including local observables, entanglement production, and Loschmidt amplitudes using Monte Carlo algorithms and demonstrate the accuracy of this approach by comparisons to exact results. We include a mapping to equivalent artificial neural networks, which were recently introduced to provide a universal structure for classical network wave functions.

TY  - JOUR
PB  - SciPost Foundation
DO  - 10.21468/SciPostPhys.4.2.013
TI  - Quantum dynamics in transverse-field Ising models from classical networks
PY  - 2018/02/28
UR  - https://scipost.org/SciPostPhys.4.2.013
JF  - SciPost Physics
JA  - SciPost Phys.
VL  - 4
IS  - 2
SP  - 013
A1  - Schmitt, Markus
AU  - Heyl, Markus
AB  - The efficient representation of quantum many-body states with classical resources is a key challenge in quantum many-body theory. In this work we analytically construct classical networks for the description of the quantum dynamics in transverse-field Ising models that can be solved efficiently using Monte Carlo techniques. Our perturbative construction encodes time-evolved quantum states of spin-1/2 systems in a network of classical spins with local couplings and can be directly generalized to other spin systems and higher spins. Using this construction we compute the transient dynamics in one, two, and three dimensions including local observables, entanglement production, and Loschmidt amplitudes using Monte Carlo algorithms and demonstrate the accuracy of this approach by comparisons to exact results. We include a mapping to equivalent artificial neural networks, which were recently introduced to provide a universal structure for classical network wave functions.
ER  -

@Article{10.21468/SciPostPhys.4.2.013,
	title={{Quantum dynamics in transverse-field Ising models from classical networks}},
	author={Markus Schmitt and Markus Heyl},
	journal={SciPost Phys.},
	volume={4},
	pages={013},
	year={2018},
	publisher={SciPost},
	doi={10.21468/SciPostPhys.4.2.013},
	url={https://scipost.org/10.21468/SciPostPhys.4.2.013},
}

Cited by 45

Czischek,
, 53 (2020) [Crossref]
Melko et al., Restricted Boltzmann machines in quantum physics
Nat. Phys. 15, 887 (2019) [Crossref]
Saito, Method to Solve Quantum Few-Body Problems with Artificial Neural Networks
J. Phys. Soc. Jpn. 87, 074002 (2018) [Crossref]
Li et al., Extracting critical exponents by finite-size scaling with convolutional neural networks
Phys. Rev. B 99, 075418 (2019) [Crossref]
De Tomasi et al., Efficiently solving the dynamics of many-body localized systems at strong disorder
Phys. Rev. B 99, 241114 (2019) [Crossref]
Karpov et al., Disorder-Free Localization in an Interacting 2D Lattice Gauge Theory
Phys. Rev. Lett. 126, 130401 (2021) [Crossref]
Matty et al., Entanglement clustering for ground-stateable quantum many-body states
Phys. Rev. Research 3, 023212 (2021) [Crossref]
Faridfar et al., Dynamical quantum phase transitions in Stark quantum spin chains
Physica A: Statistical Mechanics and its Applications 619, 128732 128732 (2023) [Crossref]
Burau et al., Unitary Long-Time Evolution with Quantum Renormalization Groups and Artificial Neural Networks
Phys. Rev. Lett. 127, 050601 (2021) [Crossref]
Kim et al., Real-time dynamics of one-dimensional and two-dimensional bosonic quantum matter deep in the many-body localized phase
Phys. Rev. B 104, 144205 (2021) [Crossref]
Vargas-Hernández et al.,
968, 171 (2020) [Crossref]
Czischek,
, 111 (2020) [Crossref]
Verdel et al., Variational classical networks for dynamics in interacting quantum matter
Phys. Rev. B 103, 165103 (2021) [Crossref]
van Nieuwenburg et al., Learning phase transitions from dynamics
Phys. Rev. B 98, 060301 (2018) [Crossref]
Gutiérrez et al., Real time evolution with neural-network quantum states
Quantum 6, 627 627 (2022) [Crossref]
Czischek et al., Quenches near criticality of the quantum Ising chain—power and limitations of the discrete truncated Wigner approximation
Quantum Sci. Technol. 4, 014006 (2018) [Crossref]
De Nicola et al., Stochastic approach to non-equilibrium quantum spin systems
J. Phys. A: Math. Theor. 52, 05LT02 (2019) [Crossref]
Tepaske et al., Three-dimensional isometric tensor networks
Phys. Rev. Research 3, 023236 (2021) [Crossref]
Deng, Machine Learning Detection of Bell Nonlocality in Quantum Many-Body Systems
Phys. Rev. Lett. 120, 240402 (2018) [Crossref]
Hartmann et al., Neural-Network Approach to Dissipative Quantum Many-Body Dynamics
Phys. Rev. Lett. 122, 250502 (2019) [Crossref]
Czischek et al., Quenches near Ising quantum criticality as a challenge for artificial neural networks
Phys. Rev. B 98, 024311 (2018) [Crossref]
Carleo et al., Machine learning and the physical sciences
Rev. Mod. Phys. 91, 045002 (2019) [Crossref]
Trapin et al., Constructing effective free energies for dynamical quantum phase transitions in the transverse-field Ising chain
Phys. Rev. B 97, 174303 (2018) [Crossref]
Matty et al., Multifaceted machine learning of competing orders in disordered interacting systems
Phys. Rev. B 100, 155141 (2019) [Crossref]
Iten et al., Discovering Physical Concepts with Neural Networks
Phys. Rev. Lett. 124, 010508 (2020) [Crossref]
Heyl, Dynamical quantum phase transitions: a review
Rep. Prog. Phys. 81, 054001 (2018) [Crossref]
Wu et al., Artificial neural network based computation for out-of-time-ordered correlators
Phys. Rev. B 101, 214308 (2020) [Crossref]
Begg et al., Trajectory-resolved Weiss fields for quantum spin dynamics
Phys. Rev. Research 5, 043288 (2023) [Crossref]
Heyl, Dynamical quantum phase transitions: A brief survey
EPL 125, 26001 (2019) [Crossref]
Kosut et al., Quantum system compression: A Hamiltonian guided walk through Hilbert space
Phys. Rev. A 103, 012406 (2021) [Crossref]
Wong et al., Loschmidt amplitude spectrum in dynamical quantum phase transitions
Phys. Rev. B 105, 174307 (2022) [Crossref]
Klassert et al., Variational learning of quantum ground states on spiking neuromorphic hardware
iScience 25, 104707 104707 (2022) [Crossref]
Kaneko et al., Dynamics of correlation spreading in low-dimensional transverse-field Ising models
Phys. Rev. A 108, 023301 (2023) [Crossref]
Wong et al., Quantum spin fluctuations in dynamical quantum phase transitions
Phys. Rev. B 108, 064305 (2023) [Crossref]
De Nicola et al., Entanglement and precession in two-dimensional dynamical quantum phase transitions
Phys. Rev. B 105, 165149 (2022) [Crossref]
Richter et al., Quantum quench dynamics in the transverse-field Ising model: A numerical expansion in linked rectangular clusters
SciPost Phys. 9, 031 (2020) [Crossref]
Schmitt et al., Quantum Many-Body Dynamics in Two Dimensions with Artificial Neural Networks
Phys. Rev. Lett. 125, 100503 (2020) [Crossref]
Zhou et al., Dynamical quantum phase transitions in non-Hermitian lattices
Phys. Rev. A 98, 022129 (2018) [Crossref]
De Nicola et al., Entanglement View of Dynamical Quantum Phase Transitions
Phys. Rev. Lett. 126, 040602 (2021) [Crossref]
Bakthavatchalam et al., Bayesian Optimization of Bose-Einstein Condensates
Sci Rep 11, 5054 (2021) [Crossref]
Valenti et al., Correlation-enhanced neural networks as interpretable variational quantum states
Phys. Rev. Research 4, L012010 (2022) [Crossref]
Yu, Dynamical phase transition and scaling in the chiral clock Potts chain
Phys. Rev. A 108, 062215 (2023) [Crossref]
Vargas-Hernández et al., Extrapolating Quantum Observables with Machine Learning: Inferring Multiple Phase Transitions from Properties of a Single Phase
Phys. Rev. Lett. 121, 255702 (2018) [Crossref]
Richter et al., Combining dynamical quantum typicality and numerical linked cluster expansions
Phys. Rev. B 99, 094419 (2019) [Crossref]
Bukov et al., Learning the ground state of a non-stoquastic quantum Hamiltonian in a rugged neural network landscape
SciPost Phys. 10, 147 (2021) [Crossref]

Ontology / Topics

See full Ontology or Topics database.

Classical networks Monte-Carlo simulations Neural networks Transverse-field Ising chain

Authors / Affiliations: mappings to Contributors and Organizations

See all Organizations.

¹ Markus Schmitt,
² Markus Heyl

Funders for the research work leading to this publication

Deutsche Forschungsgemeinschaft / German Research FoundationDeutsche Forschungsgemeinschaft [DFG]
Studienstiftung des Deutschen Volkes (through Organization: Studienstiftung des deutschen Volkes / German National Academic Foundation)