Nanophotonics (Jan 2023)

Nanophotonic quantum sensing with engineered spin-optic coupling

  • Kim Laura,
  • Choi Hyeongrak,
  • Trusheim Matthew E.,
  • Wang Hanfeng,
  • Englund Dirk R.

DOI
https://doi.org/10.1515/nanoph-2022-0682
Journal volume & issue
Vol. 12, no. 3
pp. 441 – 449

Abstract

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Nitrogen vacancy centers in diamond provide a spin-based qubit system with long coherence time even at room temperature, making them suitable ambient-condition quantum sensors for quantities including electromagnetic fields, temperature, and rotation. The optically addressable level structures of NV spins allow transduction of spin information onto light-field intensity. The sub-optimal readout fidelity of conventional fluorescence measurement remains a significant drawback for room-temperature ensemble sensing. Here, we discuss nanophotonic interfaces that provide opportunities to achieve near-unity readout fidelity based on IR absorption via resonantly enhanced spin-optic coupling. Spin-coupled resonant nanophotonic devices are projected to particularly benefit applications that utilize micro- to nanoscale sensing volume and to outperform present methods in their volume-normalized sensitivity.

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