Floquet engineering via quantum resonances in periodically driven rotors enables analytical control of tight-binding parameters in momentum-space lattices, experimentally realized with a Bose-Einstein condensate to simulate the Rice-Mele model and related configurations.
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Symmetries of potentials in many-body quantum kicked rotors at resonance produce three regimes of wavepacket spreading and bipartite entanglement entropy: quadratic growth, period-2 oscillation, or hybrid.
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Floquet engineering of tight-binding Hamiltonians in momentum space lattices
Floquet engineering via quantum resonances in periodically driven rotors enables analytical control of tight-binding parameters in momentum-space lattices, experimentally realized with a Bose-Einstein condensate to simulate the Rice-Mele model and related configurations.
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Dynamics of wavepackets and entanglement in many-body kicked rotors under quantum resonance
Symmetries of potentials in many-body quantum kicked rotors at resonance produce three regimes of wavepacket spreading and bipartite entanglement entropy: quadratic growth, period-2 oscillation, or hybrid.