Loss mechanisms in superconducting thin film microwave resonators

Jan Goetz; Frank Deppe; Max Haeberlein; Friedrich Wulschner; Christoph W. Zollitsch; Sebastian Meier; Michael Fischer; Peter Eder; Edwar Xie; Kirill G. Fedorov; Edwin P. Menzel; Achim Marx; Rudolf Gross

doi:10.1063/1.4939299

Loss mechanisms in superconducting thin film microwave resonators

Jan Goetz, Frank Deppe, Max Haeberlein, Friedrich Wulschner, Christoph W. Zollitsch, Sebastian Meier, Michael Fischer, Peter Eder, Edwar Xie, Kirill G. Fedorov, Edwin P. Menzel, Achim Marx, Rudolf Gross

Chair of Technical Physics

Research output: Contribution to journal › Article › peer-review

44 Scopus citations

Abstract

We present a systematic analysis of the internal losses of superconducting coplanar waveguide microwave resonators based on niobium thin films on silicon substrates. In particular, we investigate losses introduced by Nb/Al interfaces in the center conductor, which is important for experiments where Al based Josephson junctions are integrated into Nb based circuits. We find that these interfaces can be a strong source for two-level state (TLS) losses, when the interfaces are not positioned at current nodes of the resonator. In addition to TLS losses, for resonators including Al, quasiparticle losses become relevant above 200 mK. Finally, we investigate how losses generated by eddy currents in conductive material on the backside of the substrate can be minimized by using thick enough substrates or metals with high conductivity on the substrate backside.

Original language	English
Article number	015304
Journal	Journal of Applied Physics
Volume	119
Issue number	1
DOIs	https://doi.org/10.1063/1.4939299
State	Published - 7 Jan 2016

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abstract = "We present a systematic analysis of the internal losses of superconducting coplanar waveguide microwave resonators based on niobium thin films on silicon substrates. In particular, we investigate losses introduced by Nb/Al interfaces in the center conductor, which is important for experiments where Al based Josephson junctions are integrated into Nb based circuits. We find that these interfaces can be a strong source for two-level state (TLS) losses, when the interfaces are not positioned at current nodes of the resonator. In addition to TLS losses, for resonators including Al, quasiparticle losses become relevant above 200 mK. Finally, we investigate how losses generated by eddy currents in conductive material on the backside of the substrate can be minimized by using thick enough substrates or metals with high conductivity on the substrate backside.",

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AU - Goetz, Jan

AU - Deppe, Frank

AU - Haeberlein, Max

AU - Wulschner, Friedrich

AU - Zollitsch, Christoph W.

AU - Meier, Sebastian

AU - Fischer, Michael

AU - Eder, Peter

AU - Xie, Edwar

AU - Fedorov, Kirill G.

AU - Menzel, Edwin P.

AU - Marx, Achim

AU - Gross, Rudolf

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AB - We present a systematic analysis of the internal losses of superconducting coplanar waveguide microwave resonators based on niobium thin films on silicon substrates. In particular, we investigate losses introduced by Nb/Al interfaces in the center conductor, which is important for experiments where Al based Josephson junctions are integrated into Nb based circuits. We find that these interfaces can be a strong source for two-level state (TLS) losses, when the interfaces are not positioned at current nodes of the resonator. In addition to TLS losses, for resonators including Al, quasiparticle losses become relevant above 200 mK. Finally, we investigate how losses generated by eddy currents in conductive material on the backside of the substrate can be minimized by using thick enough substrates or metals with high conductivity on the substrate backside.

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Loss mechanisms in superconducting thin film microwave resonators

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