Liquid-nitrogen cooled, free-running single-photon sensitive detector at telecommunication wavelengths

TL;DR

This paper presents a liquid-nitrogen cooled, free-running single-photon detector at telecommunication wavelengths, offering enhanced stability and flexibility for quantum optics applications, especially in fiber-optic quantum communication.

Contribution

The study introduces a liquid-nitrogen cooled NFAD detector with a broad stable temperature range, improving upon bulky commercial cooling systems for single-photon detection at telecom wavelengths.

Findings

Achieved stable operation over a wide temperature range.

Demonstrated compatibility with photon counting tasks.

Enhanced detector performance compared to previous cooling methods.

Abstract

The measurement of light characteristics at the single- and few photon level plays a key role in many quantum optics applications. Often photodetection is preceded with the transmission of quantum light over long distances in optical fibers with their low loss window near 1550nm. Nonetheless, the detection of the photonic states at telecommunication wavelengths via avalanche photodetectors has long been facing severe restrictions. Only recently, demonstrations of the first free-running detector techniques in the telecommunication band have lifted the demand of synchronizing the signal with the detector. Moreover, moderate cooling is required to gain single-photon sensitivity with these detectors. Here we implement a liquid-nitrogen cooled negative-feedback avalanche diode (NFAD) at telecommunication wavelengths and investigate the properties of this highly flexible, free-running single-photon sensitive detector. Our realization of cooling provides a large range of stable operating temperatures and has advantages over the relatively bulky commercial refrigerators that have been used before. We determine the region of NFAD working parameters most suitable for single-photon sensitive detection enabling a direct plug-in of our detector to a true photon counting task.