Abstract
Quantum emitters in hexagonal boron nitride (hBN) are emerging as bright and robust sources of single photons for applications in quantum optics. In this work we present detailed studies on the limiting factors to achieve Fourier transform limited spectral lines. Specifically, we study phonon dephasing and spectral diffusion of quantum emitters in hBN via resonant excitation spectroscopy at cryogenic temperatures. We show that the linewidths of hBN quantum emitters are phonon broadened, even at 5 K, with typical values of the order of ∼ 1 G H z . While spectral diffusion dominates at increasing pump powers, it can be minimized by working well below saturation excitation power. Our results are important for future utilization of quantum emitters in hBN for quantum interference experiments.
Highlights
Solid state quantum light sources are emerging as promising candidates for many applications in quantum technologies[1,2,3]
Optically active point defects in hexagonal boron nitride are attracting considerable attention due to their extreme brightness, and high Debye Waller factor which means the majority of the photons are emitted into the zero phonon line (ZPL)[4,5,6,7,8]
Numerous recent studies have shown that several defects in hexagonal boron nitride (hBN) exhibit spin dependent optical transitions, and exhibit optically detected magnetic resonance (ODMR), which is vital for their employment as solid state qubits and quantum sensors at the nano-scale [12,13,14]
Summary
Solid state quantum light sources are emerging as promising candidates for many applications in quantum technologies[1,2,3]. Studies of dephasing mechanisms[19,20], coherence and line broadening effects underpin the applicability of quantum emitters for photon interference experiments. We employ coherent excitation spectroscopy at cryogenic temperatures to study the dephasing of quantum emitters in hBN.
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