Reducing two-level-system microwave loss in niobium resonators with nitrogen plasma passivation
ORAL
Abstract
Microwave loss in niobium metallic structures used in superconducting quantum circuits is limited by a native oxide layer that grows back within hours after removal. This regrowth behavior prevents the incorporation of low loss niobium components in state-of-the-art superconducting quantum processors. We show that a low temperature nitrogen plasma treatment forms a 5 nm thick niobium nitride passivation layer which suppresses the presence of surface oxide. X-ray photoelectron spectroscopy measurements confirm the presence of nitrogen atoms and a suppressed oxygen concentration, which remain stable after 15 days of aging in an ambient environment. Cryogenic microwave transmission measurements of passivated niobium coplanar waveguide resonators reveal a filling factor adjusted two-level-system loss tangent that is 4 times lower than unpassivated devices.
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Publication: K. Zheng, et. al., Nitrogen plasma passivated niobium resonators for superconducting circuits, manuscript in preparation.
Presenters
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Kaiwen Zheng
Washington University, Washington University, St. Louis
Authors
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Kaiwen Zheng
Washington University, Washington University, St. Louis
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Daria Kowsari
Washington University, St. Louis
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Nathan J Thobaben
Saint Louis University
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Xinyi Du
Washington University, St. Louis
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Sheng Ran
Washington University, St. Louis
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Erik A Henriksen
Washington University, St. Louis
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David S Wisbey
Saint Louis University
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Kater W Murch
Washington University, St. Louis