Superconducting Microstrip Losses at Microwave and Submillimeter Wavelengths

Journal article (2021)

Authors

S.A. Hähnle SRON–Netherlands Institute for Space Research, Tera-Hertz Sensing - EEMCS
K. Kouwenhoven SRON–Netherlands Institute for Space Research, Tera-Hertz Sensing - EEMCS
B.T. Buijtendorp Tera-Hertz Sensing - EEMCS
A. Endo Kavli institute of nanoscience Delft, Tera-Hertz Sensing - EEMCS
K. Karatsu Tera-Hertz Sensing - EEMCS , SRON–Netherlands Institute for Space Research
David Thoen Tera-Hertz Sensing - EEMCS
V. Murugesan SRON–Netherlands Institute for Space Research
J.J.A. Baselmans Tera-Hertz Sensing - EEMCS , SRON–Netherlands Institute for Space Research
Research Group
Tera-Hertz Sensing (EEMCS) (TU Delft)
Copyright: © 2021 S.A. Hähnle, K. Kouwenhoven, B.T. Buijtendorp, A. Endo, K. Karatsu, David Thoen, V. Murugesan, J.J.A. Baselmans
DOI: https://doi.org/10.1103/PhysRevApplied.16.014019
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Published Date

2021

Language

English

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Faculty

Electrical Engineering, Mathematics and Computer Science

Department

Microelectronics

Research Group

Tera-Hertz Sensing

Abstract

We present a lab-on-chip experiment to accurately measure losses of superconducting microstrip lines at microwave and submillimeter wavelengths. The microstrips are fabricated from Nb-Ti-N, which is deposited using reactive magnetron sputtering, and amorphous silicon which is deposited using plasma-enhanced chemical vapor deposition (PECVD). Submillimeter wave losses are measured using on-chip Fabry-Perot resonators (FPRs) operating around 350 GHz. Microwave losses are measured using shunted half-wave resonators with an identical geometry and fabricated on the same chip. We measure a loss tangent of the amorphous silicon at single-photon energies of tan⁡δ=3.7±0.5×10-5 at approximately 6GHz and tan⁡δ=2.1±0.1×10-4 at 350 GHz. These results represent very low losses for deposited dielectrics, but the submillimeter wave losses are significantly higher than the microwave losses, which cannot be understood using the standard two-level system loss model.

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PhysRevApplied.16.014019.pdf
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