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This research aims to extend single-photon detection capabilities into the mid-infrared wavelengths, enhancing various applications.

February 5, 2026

Pushing The Limits of Mid-Wave Infrared Detection with Superconducting Nanowire Single-Photon Detectors

Key Points

This research aims to extend single-photon detection capabilities into the mid-infrared wavelengths, enhancing various applications.
Developed superconducting nanowire single-photon detectors for mid-wave infrared detection (3.0 µm) and short-wave infrared detection (2.2-2.3 µm).
Evaluated detection efficiencies and specific detectivity in both wavelength ranges.
Addressed challenges related to cryogenics, optics, and SNSPD design.
Achieved the best-reported system detection efficiencies for both short-wave and mid-wave infrared.
Demonstrated improved specific detectivity surpassing state-of-the-art levels.
Used mid-infrared detection to effectively characterize new materials and quantum emitters.

Abstract

Extending single-photon detection capabilities into the mid- infrared is expected to have far-reaching implications for long-wavelength quantum optics, quantum and free-space communication, astronomy, environmental monitoring, and fundamental molecular sciences. We showcase the development of short-wave infrared (2.2-2.3 µm) and mid- wave infrared (3.0 µm) superconducting nanowire single-photon detectors (SNSPDs). In both wavelength ranges, we venture beyond state-of-the-art and achieve the best-reported system detection efficiencies and specific detectivity. We discuss the challenges in cryogenics, optics, and SNSPD design and use our mid-infrared single-photon detection to characterize emerging materials platforms and quantum emitters in a previously unattainable manner.

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Pushing The Limits of Mid-Wave Infrared Detection with Superconducting Nanowire Single-Photon Detectors

Key Points

Abstract

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