Exact Solvability Of Entanglement For Arbitrary Initial State in an Infinite-Range Floquet System

Abstract

Sharma and Bhosale [https://journals.aps.org/prb/abstract/10.1103/PhysRevB.109.014412Phys. Rev. B 109, 014412 (2024); https://journals.aps.org/prb/abstract/10.1103/PhysRevB.110.064313Phys. Rev. B 110, 064313,(2024)] recently introduced an N-spin Floquet model with infinite-range Ising interactions. There, we have shown that the model exhibits the signatures of quantum integrability for specific parameter values J=1,1/2 and τ=π/4. We have found analytically the eigensystem and the time evolution of the unitary operator for finite values of N up to 12 qubits. We have calculated the reduced density matrix, its eigensystem, time-evolved linear entropy, and the time-evolved concurrence for the initial states 0,0 and π/2,-π/2. For the general case N>12, we have provided sufficient numerical evidences for the signatures of quantum integrability, such as the degenerate spectrum, the exact periodic nature of entanglement dynamics, and the time-evolved unitary operator. In this paper, we have extended these calculations to arbitrary initial state θ0,φ0, such that θ0 ∈ [0,π] and φ0 ∈ [-π,π]. Along with that, we have analytically calculated the expression for the average linear entropy for arbitrary initial states. We numerically find that the average value of time-evolved concurrence for arbitrary initial states decreases with N, implying the multipartite nature of entanglement. We numerically show that the values S/SMax → 1 for Ising strength (J≠1,1/2), while for J=1 and 1/2, it deviates from 1 for arbitrary initial states even though the thermodynamic limit does not exist in our model. This deviation is shown to be a signature of integrability in earlier studies where the thermodynamic limit exist.

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