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In quantum technologies, it is essential to understand and exploit the interplay of light and matter. We introduce an approach creating and maintaining the coherence of four oscillators: a global microwave reference field, a polarization-gradient traveling-wave pattern of light, and the spin and motional states of a single trapped ion. Our method employs a UV light pattern capable of achieving a gigahertz-modulation bandwidth, here demonstrated in the megahertz regime, allowing for stroboscopic tracking of dynamic changes in phase space. We achieve noise floors of 1. 8 (2) 0. 16em{0ex}nm for position and 8 (2) 4. pt{0ex}zN0. 16em{0ex}0. 16em{0ex}s for momentum observables, superresolving variations on timescales 100 ns. The implications of our findings contribute to enhancing quantum control and metrological applications.
Hasse et al. (Mon,) studied this question.
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