Single-Photon Detection in Few-Layer NbSe$_2$ Superconducting Nanowires

TL;DR

This paper demonstrates single-photon detection using few-layer NbSe$_2$ superconducting nanowires, achieving high efficiency, low dark counts, and fast timing, advancing integration into quantum photonic systems.

Contribution

It introduces a novel method to create superconducting nanowire detectors from 2D NbSe$_2$, enabling photon detection at multiple wavelengths with excellent performance.

Findings

Successful detection at 780 nm and 1550 nm wavelengths.

Dark-count rate below 1 Hz up to switching current.

Timing jitter below 50 ps.

Abstract

Superconducting Nanowire Single-Photon Detectors (SNSPDs) are key building blocks for photonic quantum technologies due to their ability to detect single photons with ultra-high efficiency, low dark counts and fast temporal resolution. Superconducting materials exhibiting high uniformity, large absorption cross-section and atomic-scale thickness are desirable to extend single-photon detection from the near-infrared up to the terahertz regime, where existing material choices are especially constrained. Substrate independence would further open the way to integrate detectors onto functional materials and heterostructures, enhancing performance and enabling proximal read-out of a wide range of individual excitations. Here, we top-down shape the prototypical two-dimensional superconductor niobium diselenide (NbSe$_2$) into few-layer nanowires less than 100 nm wide and demonstrate single-photon detection at 780 and 1550 nm. At the same time, the dark-count rate remains below 1 Hz up to the switching current and we achieve a timing jitter below 50 ps. We use a diffusive hot-spot model to estimate a theoretical cut-off wavelength that surpasses the millimetre range. Our results open up routes toward quantum limited detectors integrated into quantum-photonic circuits and quantum devices, with the potential for novel detection capabilities and unprecedented energy sensitivity.