Related papers: Tunable and low-noise WSe$_2$ quantum emitters for quantum photonics

Tunable and low-noise WSe$_2$ quantum emitters for quantum photonics

URL: http://arxiv.org/abs/2507.03355v1
Date: Fri, 04 Jul 2025 07:44:03 GMT
Title: Tunable and low-noise WSe$_2$ quantum emitters for quantum photonics
Authors: Athanasios Paralikis, Pawel Wyborski, Pietro Metuh, Niels Gregersen, Battulga Munkhbat,
Abstract summary: We show that hBN encapsulation alone suppresses spectral wandering and narrows emission linewidths in WSe$$ quantum emitters.<n>Time-resolved and second-order correlation measurements confirm stable mono-exponential decay and high single-photon purity.<n>These results provide a robust framework for developing and evaluating low-noise, tunable WSe$$ quantum emitters.
Score: 0.0
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Low-noise and tunable single-photon sources are essential components of photonic quantum technologies. However, in WSe$_2$ quantum emitters, charge noise from fluctuations in their local electrostatic environment remains a major obstacle to achieving transform-limited single-photon emission and high photon indistinguishability. Here, we systematically investigate two noise mitigation strategies in hexagonal boron nitride (hBN) encapsulation and electrostatic biasing. We demonstrate that hBN encapsulation alone suppresses spectral wandering (from $\sim$170 $\mu$eV to $\sim$40 $\mu$eV) and narrows emission linewidths (from $\sim$500 $\mu$eV to $\sim$150 $\mu$eV), while applied bias enables stable Stark tuning over a 280 $\mu$eV range and further linewidth narrowing down to $\sim$100 $\mu$eV reaching the resolution-limited regime. Time-resolved and second-order correlation measurements confirm stable mono-exponential decay and high single-photon purity ($g^{(2)}(0) \approx 0.01$) with no observable blinking. To quantify progress toward the transform limit, we define two figures of merit: the linewidth ratio $R = W_{\text{exp}} / W_{\text{rad}}$ and total broadening $\Delta W = W_{\text{exp}} - W_{\text{rad}}$, with both being reduced more than five-fold in optimized devices. These results provide a robust framework for developing and evaluating low-noise, tunable WSe$_2$ quantum emitters, potentially realizing electrically controllable sources of indistinguishable single-photons for future photonic quantum technologies.

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