Micromotion enables high-fidelity fast entangling gates on radial modes of trapped-ion crystals with operation times of hundreds of nanoseconds.
High-fidelity remote entanglement of trapped atoms mediated by time-bin photons
3 Pith papers cite this work. Polarity classification is still indexing.
3
Pith papers citing it
fields
quant-ph 3years
2025 3representative citing papers
An error-resilient gate search scheme using multi-objective optimization and pulse symmetries enables microsecond two-qubit gates with fidelities approaching 99.9% in linear ion traps of up to 50 ions.
Impulsive spin-dependent excitation enables high-fidelity non-local entangling gates between arbitrary ion pairs in chains of up to 40 trapped ions within 1.3-2 center-of-mass oscillation periods.
citing papers explorer
-
Radial Fast Entangling Gates Under Micromotion in Trapped-Ion Quantum Computers
Micromotion enables high-fidelity fast entangling gates on radial modes of trapped-ion crystals with operation times of hundreds of nanoseconds.
-
Error-Resilient Fast Entangling Gates for Scalable Ion-Trap Quantum Processors
An error-resilient gate search scheme using multi-objective optimization and pulse symmetries enables microsecond two-qubit gates with fidelities approaching 99.9% in linear ion traps of up to 50 ions.
-
High-speed and high-connectivity two-qubit gates in long chains of trapped ions
Impulsive spin-dependent excitation enables high-fidelity non-local entangling gates between arbitrary ion pairs in chains of up to 40 trapped ions within 1.3-2 center-of-mass oscillation periods.