Long-distance entanglement in Motzkin and Fredkin spin chains

Dell’Anna, Luca

doi:10.21468/scipostphys.7.4.053

Cited by 15 publications

(21 citation statements)

References 29 publications

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“…This work extends significantly the analysis done in a previous paper 12 , where violation of the cluster decomposition has been observed for the colorful versions of the models looking at the correlation functions of spins along z-directions. The results reported here are in perfect agreement with numerical results for transverse spin correlation functions 19 and with what found for the mutual information, which remains finite even when measured between infinitely distant separated regions 21 . In this paper we considered the colorless versions of the Motzkin and Fredkin spin chains, with spins 1 and 1/2.…”

Section: Discussionsupporting

confidence: 91%

“…It has been given also a continuum description for the ground-state wavefunctions of those models, which can reproduce quite well some quantities as for example the local magnetization and the entanglement entropy, and whose scaling Hamiltonian is not conformally invariant 19 . Entanglement properties in these models have also been extensively studied, particularly the Renyi entropy 20 , the negativity and the mutual information, revealing a large-distance entanglement behavior 21 , which can produce intriguing out-of equilibrium properties 22 .…”

Section: Introductionmentioning

confidence: 99%

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Dynamics and correlations in Motzkin and Fredkin spin chains

Dell’Anna¹,

Barbiero²,

Trombettoni³

2019

J. Stat. Mech.

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The Motzkin and Fredkin quantum spin chains are described by frustration-free Hamiltonians recently introduced and studied because of their anomalous behaviors in the correlation functions and in the entanglement properties. In this paper we analyze their quantum dynamical properties, focusing in particular on the time evolution of the excitations driven by a quantum quench, looking at the correlations functions of spin operators defined along different directions, and discussing the results in relation with the cluster decomposition property. arXiv:1906.09515v1 [cond-mat.stat-mech]

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Section: Discussionsupporting

confidence: 91%

Section: Introductionmentioning

confidence: 99%

Dynamics and correlations in Motzkin and Fredkin spin chains

Dell’Anna¹,

Barbiero²,

Trombettoni³

2019

J. Stat. Mech.

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“…Correlation functions can be shown to match as well. However, our field theory result (95) for the (Rényi) entropy of a bulk interval does not agree with the spin chains calculations [41,64]. Our formula does reproduce the 'geometric' part (i.e.…”

Section: B Relation To Motzkin and Fredkin Chainscontrasting

confidence: 69%

Entanglement and separability in continuum Rokhsar-Kivelson states

Boudreault¹,

Berthiere²,

Witczak-Krempa³

2021

Preprint

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Starting from the (d + 1)-dimensional Lifshitz critical boson with dynamical exponent z = 2, we propose two nontrivial deformations that preserve the Rokhsar-Kivelson structure where the groundstate is encoded in an underlying, local d-dimensional QFT. Specializing to d = 1 spatial dimension, the first deformation maps the groundstate to the quantum harmonic oscillator, leading to a gap for the scalar. We study the resulting correlation functions, and find that Cluster Decomposition is restored. The special form of the groundstate allows to analytically compute the c-function for the entanglement entropy along a renormalization group (RG) flow for the wavefunction, which is found to be strictly decreasing as in conformal field theories (CFTs). From the entropic c-function, we obtain the corner term for the z = 2 Lifshitz critical boson in (2+1)D in the small angle limit. The second deformation is non-Gaussian and yields a groundstate described by SL(2, R)-conformal quantum mechanics. This deformation preserves the conformal spatial symmetry of the groundstate, and constrains the form of the correlators and entanglement entropy. As a byproduct of our calculations, we obtain explicit results for the capacity of entanglement in Lifshitz theories and discuss their interpretation. We also prove the separability of the reduced density matrix of two disconnected subsystems for real-valued RK wavefunctions, implying the vanishing of logarithmic negativity. Finally, we comment on the relations to certain stoquastic quantum spin chains, the Motzkin and Fredkin chains.

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“…In that case, it will be nice if any technique is developed to obtain the relevant one-point functions 1 N tr M 2n and 1 N tr (M n+r XM n−r X) with M = ∑ s f =1 M f . It will also be worth doing analogous investigation for other entanglement measures like Rényi entanglement entropy [10,11] and mutual information [19], and extending to deformed Motzkin/Fredkin spin chains in which the EEs grow linearly [20][21][22].…”

Section: Discussionmentioning

confidence: 99%

“…which is an extension of Equation (19) with Equations ( 44) and (45), thereby removing the restriction to the tree diagrams. Equation ( 53) is evaluated around the critical point.…”

Section: Case Of Fredkin Spin Chainmentioning

confidence: 99%

Highly Entangled Spin Chains and 2D Quantum Gravity

Sugino

2020

Symmetry

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Motzkin and Fredkin spin chains exhibit the extraordinary amount of entanglement scaling as a square-root of the volume, which is beyond logarithmic scaling in the ordinary critical systems. Intensive study of such spin systems is urged to reveal novel features of quantum entanglement. As a study of the systems from a different viewpoint, we introduce large-N matrix models with so-called A B A B interactions, in which correlation functions reproduce the entanglement scaling in tree and planar Feynman diagrams. Including loop diagrams naturally defines an extension of the Motzkin and Fredkin spin chains. Contribution from the whole loop effects at large N gives the growth of the power of 3 / 2 (with logarithmic correction), further beyond the square-root scaling. The loop contribution provides fluctuating two-dimensional bulk geometry, and the enhancement of the entanglement is understood as an effect of quantum gravity.

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Long-distance entanglement in Motzkin and Fredkin spin chains

Cited by 15 publications

References 29 publications

Dynamics and correlations in Motzkin and Fredkin spin chains

Dynamics and correlations in Motzkin and Fredkin spin chains

Entanglement and separability in continuum Rokhsar-Kivelson states

Highly Entangled Spin Chains and 2D Quantum Gravity

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