Floquet scars and prethermal fragmentation in a driven spin-one chain
Abstract
We study the periodic dynamics of a spin-one chain driven using a square-pulse protocol with amplitude Q0 and frequency ωD. The Hamiltonian of the spin chain hosts a thermodynamically large number of Z2-valued conserved quantities W on the links . This allows us to study the Floquet dynamics of this chain within a given sector with fixed values of W. For the sector with all W=1, we find signatures of quantum many-body scar states for ωD Q0; they lead to oscillatory dynamics and fidelity revival for specific initial states. Upon lowering ωD, we find an ergodic regime exhibiting fast thermalization consistent with the prediction of the (Floquet) eigenstate thermalization hypothesis. In addition, we identify special drive frequencies ωn= Q0/(2n ) (where n = 1, 2, 3, ·s) at which the Floquet Hamiltonian exhibits prethermal strong Hilbert space fragmentation (HSF) with the largest fragment being ergodic; in contrast, a weak HSF is found at ω'n= Q0/[(2n+1)] (where n = 0, 1, 2, ·s). We also study the sector with W =\·s 1,1,-1,1,1,-1 ·s \ which shows strong HSF at ωn but no fragmentation at ω'n. Our analysis indicates that the strong HSF in this sector harbors an integrable largest fragment. We provide numerical support for our analytical and perturbative results using exact-diagonalization (ED) studies on finite chains of length L 24. Our numerical results for entanglement entropy, fidelity, and correlation functions of the driven chain provide definitive signatures of prethermal strong HSF for both sectors.
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