Simulating Hydrodynamics on Noisy Intermediate-Scale Quantum Devices with Random Circuits

Richter, Jonas; Pal, Arijeet

doi:10.1103/physrevlett.126.230501

Cited by 42 publications

(43 citation statements)

References 85 publications

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“…5 the decay of C (M) (t ) for the same values of and a fixed edge length L x = L y = 5. The overall situation appears to be similar to the one for the quasi-1D two-leg ladder, e.g., the relaxation is well described by a power law t −α with a diffusive exponent α, which is α = 1 in this 2D case [7]. For = 0.5 in Fig.…”

Section: Quasi-1d Two-leg Ladder and 2d Square Latticesupporting

confidence: 57%

“…( 22) and the constant c is chosen in such a way that ρ r + c has nonnegative eigenvalues. Then, the correlation function can be rewritten as a standard expectation value [7,57,80],…”

Section: A Dynamical Quantum Typicalitymentioning

confidence: 99%

“…Understanding the properties of quantum many-body systems out of equilibrium is a notoriously difficult task with relevance to various areas of modern physics, ranging from fundamental aspects of statistical mechanics [1,2] to more applied issues in material science and quantum information technology. Quantum spin systems are of particular importance in this context, since they describe the magnetism of certain compounds in nature [3], can be realized in new experimental platforms [4,5], or can be simulated on already available or future quantum computers [6,7].…”

Section: Introductionmentioning

confidence: 99%

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Quantum versus classical dynamics in spin models: Chains, ladders, and square lattices

et al. 2021

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We present a comprehensive comparison of spin and energy dynamics in quantum and classical spin models on different geometries, ranging from one-dimensional chains, over quasi-one-dimensional ladders, to twodimensional square lattices. Focusing on dynamics at formally infinite temperature, we particularly consider the autocorrelation functions of local densities, where the time evolution is governed either by the linear Schrödinger equation in the quantum case or the nonlinear Hamiltonian equations of motion in the case of classical mechanics. While, in full generality, a quantitative agreement between quantum and classical dynamics can therefore not be expected, our large-scale numerical results for spin-1/2 systems with up to N = 36 lattice sites in fact defy this expectation. Specifically, we observe a remarkably good agreement for all geometries, which is best for the nonintegrable quantum models in quasi-one or two dimensions, but still satisfactory in the case of integrable chains, at least if transport properties are not dominated by the extensive number of conservation laws. Our findings indicate that classical or semiclassical simulations provide a meaningful strategy to analyze the dynamics of quantum many-body models, even in cases where the spin quantum number S = 1/2 is small and far away from the classical limit S → ∞.

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Section: Quasi-1d Two-leg Ladder and 2d Square Latticesupporting

confidence: 57%

“…( 22) and the constant c is chosen in such a way that ρ r + c has nonnegative eigenvalues. Then, the correlation function can be rewritten as a standard expectation value [7,57,80],…”

Section: A Dynamical Quantum Typicalitymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Quantum versus classical dynamics in spin models: Chains, ladders, and square lattices

et al. 2021

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“…Still, a direct sampling of states is practically limited to small fractions of the computational basis (0.05% in this case) and would suffer from the exponential growth of the Hilbert space on larger systems. A more scalable alternative is to use random, highly entangled states to directly measure spectrally averaged quantities (quantum typicality 37 – 39 ; see Supplementary Information). The autocorrelator averaged over all bit strings agrees, up to an error exponentially small in , with , where ⟩ is a typical Haar-random many-body state in the Hilbert space of qubits.…”

Section: Mainmentioning

confidence: 99%

Time-crystalline eigenstate order on a quantum processor

Ippoliti

Quintana

et al. 2021

Nature

181

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This is a PDF file of a peer-reviewed paper that has been accepted for publication. Although unedited, the content has been subjected to preliminary formatting. Nature is providing this early version of the typeset paper as a service to our authors and readers. The text and figures will undergo copyediting and a proof review before the paper is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers apply.

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“…Here, we present an algorithm for generating canonical TPQ states on quantum computers with low quantum resource requirements, enabling the estimation of finite temperature properties of materials on NISQ devices. Our algorithm relies on a straightforward and scalable protocol for preparing the random state [25], which allows for circuit depths to be tuned to find a balance between desired accuracy and feasibility of execution on NISQ hardware. Furthermore, the algorithm is agnostic to implementation of the non-unitary transformation of the random state, which can be tailored to the resource constraints of different quantum devices.…”

mentioning

confidence: 99%