Multi-Line Superconducting Waveguides Based on YBCO-on-Kapton Technology

Vyacheslav Solovyov; Hyunwoo Kim; Paul Farrell

doi:10.1109/TASC.2023.3347187

Multi-Line Superconducting Waveguides Based on YBCO-on-Kapton Technology

Vyacheslav Solovyov
, Hyunwoo Kim
, Paul Farrell

Center for Advanced Technology in Integrated Electrical Energy Systems

Brookhaven Technology Group

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

2 Scopus citations

Abstract

Coplanar (with the ground) and stripline 25 cm long waveguides are manufactured from the YBCO-Kapton material. The waveguides are intended as the key components of a scalable signal delivery for large quantum computing systems and detectors. The waveguide is coupled with an integrated power divider that replaces the standard attenuator. The divider is designed to return most of the power to the previous thermalization stage. The method is projected to reduce the active dissipation by ≈10. We investigate the effect of internal strain in YBCO layer on the device's mechanical stability. We show that adhesives with high stiffness are essential for the reliability of YBCO-Kapton devices.

Original language	English
Article number	1500205
Pages (from-to)	1-5
Number of pages	5
Journal	IEEE Transactions on Applied Superconductivity
Volume	34
Issue number	3
DOIs	https://doi.org/10.1109/TASC.2023.3347187
State	Published - May 1 2024

Keywords

High-temperature superconductors
quantum computing
RF properties
scalable interface

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10.1109/TASC.2023.3347187

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abstract = "Coplanar (with the ground) and stripline 25 cm long waveguides are manufactured from the YBCO-Kapton material. The waveguides are intended as the key components of a scalable signal delivery for large quantum computing systems and detectors. The waveguide is coupled with an integrated power divider that replaces the standard attenuator. The divider is designed to return most of the power to the previous thermalization stage. The method is projected to reduce the active dissipation by ≈10. We investigate the effect of internal strain in YBCO layer on the device's mechanical stability. We show that adhesives with high stiffness are essential for the reliability of YBCO-Kapton devices.",

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AU - Farrell, Paul

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AB - Coplanar (with the ground) and stripline 25 cm long waveguides are manufactured from the YBCO-Kapton material. The waveguides are intended as the key components of a scalable signal delivery for large quantum computing systems and detectors. The waveguide is coupled with an integrated power divider that replaces the standard attenuator. The divider is designed to return most of the power to the previous thermalization stage. The method is projected to reduce the active dissipation by ≈10. We investigate the effect of internal strain in YBCO layer on the device's mechanical stability. We show that adhesives with high stiffness are essential for the reliability of YBCO-Kapton devices.

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KW - RF properties

KW - scalable interface

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Multi-Line Superconducting Waveguides Based on YBCO-on-Kapton Technology

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Keywords

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