Impulsive Spin-Motion Entanglement for Fast Quantum Computation and Sensing
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We perform entanglement of spin and motional degrees of freedom of a single, ground-state trapped ion through the application of a $16$ ps laser pulse. The duration of the interaction is significantly shorter than both the motional timescale ($30$ $\mu$s) and spin precession timescale ($1$ ns) , demonstrating that neither sets a fundamental speed limit on this operation for quantum information processing. Entanglement is demonstrated through the collapse and revival of spin coherence as the spin components of the wavefunction separate and recombine in phase space. We infer the fidelity of these single qubit operations to be $(97^{+3}_{-4})\%$.
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Cited by 2 Pith papers
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Fidelity bounds for spin-dependent kicks with pulsed lasers
Finite pulse duration is the dominant infidelity source in single-ion SDKs, enabling infidelities below 10^{-3} with ≳10 equispaced picosecond pulses over nanosecond SDK times.
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