Extracting the Field Theory Description of a Quantum Many-Body System from Experimental Data

Zache, Torsten V.; Schweigler, Thomas; Erne, Sebastian; Schmiedmayer, Jörg; Berges, Jürgen

doi:10.1103/physrevx.10.011020

Cited by 52 publications

(43 citation statements)

References 45 publications

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“…While digital quantum simulations based on a Trotterized time evolution on a universal quantum computer are challenging to scale up, present large scale analog quantum simulators using ultracold quantum gases already explore the many-body limit described by quantum field theory [54,55,[647][648][649][650][651][652][653][654][655][656][657][658][659][660][661][662][663]. In principle, with quantum simulators non-universal aspects of the dynamics of gauge theories can be studied.…”

Section: Interdisciplinary Connectionsmentioning

confidence: 99%

QCD thermalization: Ab initio approaches and interdisciplinary connections

et al. 2021

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Section: Interdisciplinary Connectionsmentioning

confidence: 99%

QCD thermalization: Ab initio approaches and interdisciplinary connections

et al. 2021

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“…While there are many different ways of driving a Bose gas away from equilibrium, it has recently been demonstrated experimentally that the subsequent relaxation dynamics can exhibit universal properties that are insensitive to the details of the initial conditions and system parameters [22][23][24]. Theoretical results based on field correlation functions indicate that vastly different systems far from equilibrium may share very similar universal scaling properties, ranging from post-inflationary dynamics in the early universe [25,26], and ultrarelativistic collision experiments with heavy nuclei [27][28][29], to ultra-cold quantum gases in the laboratory [30,31]. In particular, quantum as well as classical statistical field theories appear to belong to the same nonthermal universality class [32].…”

Section: Introductionmentioning

confidence: 99%

Finding self-similar behavior in quantum many-body dynamics via persistent homology

et al. 2021

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Inspired by topological data analysis techniques, we introduce persistent homology observables and apply them in a geometric analysis of the dynamics of quantum field theories. As a prototype application, we consider data from a classical-statistical simulation of a two-dimensional Bose gas far from equilibrium. We discover a continuous spectrum of dynamical scaling exponents, which provides a refined classification of nonequilibrium self-similar phenomena. A possible explanation of the underlying processes is provided in terms of mixing strong wave turbulence and anomalous vortex kinetics components in point clouds. We find that the persistent homology scaling exponents are inherently linked to the geometry of the system, as the derivation of a packing relation reveals. The approach opens new ways of analyzing quantum many-body dynamics in terms of robust topological structures beyond standard field theoretic techniques.

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“…Most interestingly, we found that, despite this agreement, both models become ever more distinguishable in terms of the fractal dimension distribution as the dimensionality of Hilbert space grows. This establishes an appealing connection with the current problem of certification of distinctive features of complex quantum systems [64][65][66][67][68], and suggests the enticing prospect of having an accessible figure of merit that could unveil the specifics of the underlying many-body Hamiltonian in the chaotic regime, which is otherwise mainly determined by universal features. We nonetheless also contemplated the possibility that such deviation could be accounted for by the more refined embedded ensembles.…”

Section: Introductionmentioning

confidence: 77%

Chaos in the Bose–Hubbard model and random two-body Hamiltonians

et al. 2021

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We investigate the chaotic phase of the Bose-Hubbard model [L. Pausch et al, Phys. Rev. Lett. 126, 150601 (2021)] in relation to the bosonic embedded random matrix ensemble, which mirrors the dominant few-body nature of many-particle interactions, and hence the Fock space sparsity of quantum many-body systems. The energy dependence of the chaotic regime is well described by the bosonic embedded ensemble, which also reproduces the Bose-Hubbard chaotic eigenvector features, quantified by the expectation value and eigenstate-to-eigenstate fluctuations of fractal dimensions. Despite this agreement, in terms of the fractal dimension distribution, these two models depart from each other and from the Gaussian orthogonal ensemble as Hilbert space grows. These results provide further evidence of a way to discriminate among different many-body Hamiltonians in the chaotic regime.

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Extracting the Field Theory Description of a Quantum Many-Body System from Experimental Data

Cited by 52 publications

References 45 publications

QCD thermalization: Ab initio approaches and interdisciplinary connections

QCD thermalization: Ab initio approaches and interdisciplinary connections

Finding self-similar behavior in quantum many-body dynamics via persistent homology

Chaos in the Bose–Hubbard model and random two-body Hamiltonians

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