A fluctuation-guided adaptive random compiler for Hamiltonian simulation dynamically adjusts term sampling probabilities according to state sensitivity to improve fidelity over fixed randomized methods.
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Proposal for a tunable, DDI-resilient controlled-phase gate in polar molecules using global microwave pulses and motional-mode separation, with predicted fidelity over 0.9999.
Quantized motion of trapped polar molecules realizes an asymmetric quantum Rabi model and trap-dipole resonance while supporting high-fidelity iSWAP and controlled-phase gates.
A laser-based scheme generates a nonlinear phonon mode in trapped ions that undergoes Hopf bifurcation to a stable limit cycle, realizing a phonon time crystal.
citing papers explorer
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Fluctuation-guided adaptive random compiler for Hamiltonian simulation
A fluctuation-guided adaptive random compiler for Hamiltonian simulation dynamically adjusts term sampling probabilities according to state sensitivity to improve fidelity over fixed randomized methods.
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High-fidelity molecular quantum logic gates resilient to interaction fluctuation
Proposal for a tunable, DDI-resilient controlled-phase gate in polar molecules using global microwave pulses and motional-mode separation, with predicted fidelity over 0.9999.
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Asymmetric quantum Rabi model, trap-dipole resonance, and quantum gates with optically trapped ultracold polar molecules
Quantized motion of trapped polar molecules realizes an asymmetric quantum Rabi model and trap-dipole resonance while supporting high-fidelity iSWAP and controlled-phase gates.
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Time Crystal in the Nonlinear Phonon Mode of the Trapped Ions
A laser-based scheme generates a nonlinear phonon mode in trapped ions that undergoes Hopf bifurcation to a stable limit cycle, realizing a phonon time crystal.