Quantum emitters in silicon: Purcell-enhanced lifetime modulation as a probe of local refractive index changes

Quantum emitters embedded in silicon photonic cavities offer a powerful and scalable platform for label-free refractive index sensing at the nanoscale. We propose and theoretically analyze a novel sensing mechanism based on Purcell-enhanced modulation of the emitter's spontaneous emission lifetime, enabling detection of refractive index changes via time-correlated single-photon counting (TCSPC). In contrast to traditional resonance-shift sensors, our approach exploits the lifetime sensitivity to variations in the local density of optical states (LDOS), providing an intensity-independent, spectrally unresolvable, and CMOS-compatible sensing modality. We derive analytical expressions linking refractive index perturbations to relative lifetime shifts and identify an optimal off-resonance operation regime, where the lifetime response becomes linear and maximally sensitive to small perturbations. Parametric evaluation of the analytical expressions shows that, for moderate-quality photonic cavities (Q = 10^5 to 10^7), this method enables refractive index detection limits as low as 10^{-9} RIU, competitive with or even outperforming state-of-the-art plasmonic and microresonator sensors, yet requiring significantly simpler instrumentation. Furthermore, we show that long-lived emitters such as T-centers in silicon provide a unique advantage, allowing sub-nanosecond lifetime shifts to be resolved with standard TCSPC systems. Although room-temperature operation of quantum emitters in silicon has yet to be demonstrated, our results lay the theoretical foundation for scalable, room-temperature, quantum-enabled sensing of refractive index changes, eliminating the need for spectral resolution and cryogenic infrastructure.