Self-heating hotspots in superconducting nanowires cooled by phonon black-body radiation

Controlling thermal transport is important for a range of devices and technologies, from phase change memories to next-generation electronics. This is especially true in nano-scale devices where thermal transport is altered by the influence of surfaces and changes in dimensionality. In superconducti...

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Bibliographic Details
Published in:Nature communications 2022-09, Vol.13 (1), p.5429-8, Article 5429
Main Authors: Dane, Andrew, Allmaras, Jason, Zhu, Di, Onen, Murat, Colangelo, Marco, Baghdadi, Reza, Tambasco, Jean-Luc, Morimoto, Yukimi, Forno, Ignacio Estay, Charaev, Ilya, Zhao, Qingyuan, Skvortsov, Mikhail, Kozorezov, Alexander, Berggren, Karl K.
Format: Article
Language:English
Subjects:
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147/135
639/166/987
639/766/119/1003
639/925/927/1064
Black body radiation
Conductance
Detectors
Devices
Electrical measurement
Electronics
Heat flow
Heat transmission
Humanities and Social Sciences
Latency
multidisciplinary
Nanotechnology
Nanotechnology devices
Nanowires
Performance measurement
Photons
Quantum efficiency
Science
Science (multidisciplinary)
Sensors
Substrates
Superconductivity
Thermal engineering
Thermal properties
Thermodynamic properties
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Summary:Controlling thermal transport is important for a range of devices and technologies, from phase change memories to next-generation electronics. This is especially true in nano-scale devices where thermal transport is altered by the influence of surfaces and changes in dimensionality. In superconducting nanowire single-photon detectors, the thermal boundary conductance between the nanowire and the substrate it is fabricated on influences all of the performance metrics that make these detectors attractive for applications. This includes the maximum count rate, latency, jitter, and quantum efficiency. Despite its importance, the study of thermal boundary conductance in superconducting nanowire devices has not been done systematically, primarily due to the lack of a straightforward characterization method. Here, we show that simple electrical measurements can be used to estimate the thermal boundary conductance between nanowires and substrates and that these measurements agree with acoustic mismatch theory across a variety of substrates. Numerical simulations allow us to refine our understanding, however, open questions remain. This work should enable thermal engineering in superconducting nanowire electronics and cryogenic detectors for improved device performance. Unlocking the ultimate potential of superconducting nanowire single photon detectors requires engineering their thermal properties. Here, the authors improve our understanding of heat flow in these devices and suggest routes to improved performance.
ISSN:2041-1723
2041-1723
DOI:10.1038/s41467-022-32719-w