Related papers: Laser-induced spectral diffusion and excited-state mixing of silicon T centres

Laser-induced spectral diffusion and excited-state mixing of silicon T centres

URL: http://arxiv.org/abs/2504.09908v1
Date: Mon, 14 Apr 2025 06:09:17 GMT
Title: Laser-induced spectral diffusion and excited-state mixing of silicon T centres
Authors: Camille Bowness, Simon A. Meynell, Michael Dobinson, Chloe Clear, Kais Jooya, Nicholas Brunelle, Mehdi Keshavarz, Katarina Boos, Melanie Gascoine, Shahrzad Taherizadegan, Christoph Simon, Mike L. W. Thewalt, Stephanie Simmons, Daniel B. Higginbottom,
Abstract summary: We study the dynamics of spectral wandering in nanophotonics-coupled, individual silicon T centres.<n>We demonstrate a 35x narrowing of the emitter linewidth to 110 MHz using a resonance-check scheme.<n>We report laser-induced spin-mixing in the excited state and discuss potential mechanisms common to both phenomena.
Score: 0.0
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: To find practical application as photon sources for entangled optical resource states or as spin-photon interfaces in entangled networks, semiconductor emitters must produce indistinguishable photons with high efficiency and spectral stability. Nanophotonic cavity integration increases efficiency and bandwidth, but it also introduces environmental charge instability and spectral diffusion. Among various candidates, silicon colour centres have emerged as compelling platforms for integrated-emitter quantum technologies. Here we investigate the dynamics of spectral wandering in nanophotonics-coupled, individual silicon T centres using spectral correlation measurements. We observe that spectral fluctuations are driven predominantly by the near-infrared excitation laser, consistent with a power-dependent Ornstein-Uhlenbeck process, and show that the spectrum is stable for up to 1.5 ms in the dark. We demonstrate a 35x narrowing of the emitter linewidth to 110 MHz using a resonance-check scheme and discuss the advantage for pairwise entanglement rates and optical resource state generators. Finally, we report laser-induced spin-mixing in the excited state and discuss potential mechanisms common to both phenomena. These effects must be considered in calibrating T centre devices for high-performance entanglement generation.

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