Litcius/Paper detail

Nanophotonic quantum sensing with engineered spin‐optic coupling

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

2023Nanophotonics19 citationsDOIOpen Access PDF

Abstract

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.

Topics & Concepts

NanophotonicsQuantum sensorNanosensorQubitSpin (aerodynamics)OptoelectronicsSpinsCoherence (philosophical gambling strategy)Coupling (piping)Absorption (acoustics)PhysicsMaterials scienceQuantumQuantum informationNanotechnologyOpticsQuantum networkCondensed matter physicsQuantum mechanicsMetallurgyThermodynamicsDiamond and Carbon-based Materials ResearchAdvanced Fiber Laser TechnologiesNonlinear Optical Materials Studies