Nonthermal eigenstates and slow relaxation in quantum Fredkin spin chains

Causer, Luke; Bañuls, Mari Carmen; Garrahan, Juan P.

doi:10.1103/physrevb.110.134322

Phys. Rev. B

2024

DOI: 10.1103/physrevb.110.134322

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Nonthermal eigenstates and slow relaxation in quantum Fredkin spin chains

Luke Causer,

Mari Carmen Bañuls,

Juan P. Garrahan

Abstract: We study the dynamics and thermalization of the Fredkin spin chain, a system with local three-body interactions, particle conservation, and explicit kinetic constraints. We consider deformations away from its stochastic point in order to tune between regimes where kinetic energy dominates and those where potential energy does. By means of exact diagonalization, perturbation theory, and variational matrix product states, we show there is a sudden change of behavior in the dynamics that occurs, from one of fast … Show more

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State-Dependent Mobility Edge in Kinetically Constrained Models

Badbaria,

Pancotti,

Singh

et al. 2024

PRX Quantum

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In this work, we show that the kinetically constrained quantum East model lies between a quantum scarred and a many-body localized system featuring an unconventional type of mobility edge in the spectrum. We name this scenario the mobility edge: while the system does not exhibit a sharp separation in energy between thermal and nonthermal eigenstates, the abundance of nonthermal eigenstates results in slow entanglement growth for initial states, such as product states, below a finite energy density. We characterize the state-dependent mobility edge by looking at the complexity of classically simulating dynamics using tensor networks for system sizes well beyond those accessible via exact diagonalization. Focusing on initial product states, we observe a qualitative change in the dynamics of the bond dimension needed as a function of their energy density. Specifically, the bond dimension typically grows in time up to a certain energy density, where we locate the state-dependent mobility edge, enabling simulations for long times. Above this energy density, the bond dimension typically grows , making the simulation practically unfeasible beyond short times, as generally expected in interacting theories. We correlate the polynomial growth of the bond dimension to the presence of many nonthermal eigenstates around that energy density, a subset of which we compute via tensor networks. The outreach of our findings encompasses quantum sampling problems and the efficient simulation of quantum circuits beyond Clifford families. Published by the American Physical Society 2024

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State-Dependent Mobility Edge in Kinetically Constrained Models

Badbaria,

Pancotti,

Singh

et al. 2024

PRX Quantum

View full text Add to dashboard Cite

show abstract

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Nonthermal eigenstates and slow relaxation in quantum Fredkin spin chains

Cited by 1 publication

References 89 publications

State-Dependent Mobility Edge in Kinetically Constrained Models

State-Dependent Mobility Edge in Kinetically Constrained Models

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