Microwave nanobolometer based on proximity Josephson junctions

Microwave nanobolometer based on proximity Josephson junctions

We introduce a microwave bolometer aimed at high-quantum-efficiency detection of wave packet energy within the framework of circuit quantum electrodynamics, the ultimate goal being single microwave photon detection. We measure the differential thermal conductance between the detector and its heat ba...

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Veröffentlicht in:Physical review. B, Condensed matter and materials physics Condensed matter and materials physics, 2014-08, Vol.90 (6), Article 064505
Hauptverfasser: Govenius, J., Lake, R. E., Tan, K. Y., Pietilä, V., Julin, J. K., Maasilta, I. J., Virtanen, P., Möttönen, M.
Format: Artikel
Sprache:eng
Schlagworte:
Bolometers
Condensed matter
Differential thermal analysis
Heat transfer
Microwaves
Nanostructure
Photons
Thermal conductivity
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Zusammenfassung:We introduce a microwave bolometer aimed at high-quantum-efficiency detection of wave packet energy within the framework of circuit quantum electrodynamics, the ultimate goal being single microwave photon detection. We measure the differential thermal conductance between the detector and its heat bath, obtaining values as low as 5 fW/K at 50 mK. This is one tenth of the thermal conductance quantum and corresponds to a theoretical lower bound on noise-equivalent power of order 10 super(-20) W/[radical]Hz at 50 mK. By measuring the differential thermal conductance of the same bolometer design in substantially different environments and materials, we determine that electron-photon coupling dominates the thermalization of our nanobolometer.
ISSN:1098-0121
1550-235X
DOI:10.1103/PhysRevB.90.064505