A Demonstration of Multifloating Superconducting Qubits on a 3-D Flip-Chip Platform With TLS Loss Mitigation via Apertures

Zhen Luo; Thomas Mayer; Daniela Zahn; Carla Moran Guizan; Johannes Weber; Simon Lang; Hannes Bender; Luis Schwarzenbach; Lars Nebrich; Rui Pereira; Amelie Hagelauer

doi:10.1109/LMWT.2025.3559221

A Demonstration of Multifloating Superconducting Qubits on a 3-D Flip-Chip Platform With TLS Loss Mitigation via Apertures

Zhen Luo
, Thomas Mayer
, Daniela Zahn
, Carla Moran Guizan
, Johannes Weber
, Simon Lang
, Hannes Bender
, Luis Schwarzenbach
, Lars Nebrich
, Rui Pereira
, Amelie Hagelauer

Chair of Micro- and Nanosystems Technology

Technical University of Munich
Fraunhofer EMFT Institute for Electronic Microsystems and Solid State Technologies

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

Abstract

Flip-chip platforms are among the most promising approaches for scaling up superconducting qubits in quantum computing. This work presents the design, modeling, and analysis of floating transmon qubits implemented on a 3-D flip-chip platform. A major focus during qubit design is addressing coherence challenges caused by two-level system (TLS) losses, particularly from surface interfaces. TLS losses at the metal-air (MA) interface are mitigated by introducing apertures beneath the qubit pads. The aperture size is optimized to balance two key factors: minimizing total TLS loss and ensuring sufficient coupling strength between the transmon and resonator. Subsequently, a packaged 3-D chip comprising 24 floating transmons is demonstrated. The transmission spectrum is measured, with all readout resonators successfully located at their designated positions on the spectrum. Two-tone spectroscopy is demonstrated, enabling precise measurement of the qubit frequency.

Original language	English
Pages (from-to)	832-835
Number of pages	4
Journal	IEEE Microwave and Wireless Technology Letters
Volume	35
Issue number	6
DOIs	https://doi.org/10.1109/LMWT.2025.3559221
State	Published - 2025

Keywords

Flip-chip integration
quantum measurement
qubit modeling
superconducting qubit
transmon
two-level system (TLS) losses

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10.1109/LMWT.2025.3559221

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Luo, Z., Mayer, T., Zahn, D., Moran Guizan, C., Weber, J., Lang, S., Bender, H., Schwarzenbach, L., Nebrich, L., Pereira, R., & Hagelauer, A. (2025). A Demonstration of Multifloating Superconducting Qubits on a 3-D Flip-Chip Platform With TLS Loss Mitigation via Apertures. IEEE Microwave and Wireless Technology Letters, 35(6), 832-835. https://doi.org/10.1109/LMWT.2025.3559221

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title = "A Demonstration of Multifloating Superconducting Qubits on a 3-D Flip-Chip Platform With TLS Loss Mitigation via Apertures",

abstract = "Flip-chip platforms are among the most promising approaches for scaling up superconducting qubits in quantum computing. This work presents the design, modeling, and analysis of floating transmon qubits implemented on a 3-D flip-chip platform. A major focus during qubit design is addressing coherence challenges caused by two-level system (TLS) losses, particularly from surface interfaces. TLS losses at the metal-air (MA) interface are mitigated by introducing apertures beneath the qubit pads. The aperture size is optimized to balance two key factors: minimizing total TLS loss and ensuring sufficient coupling strength between the transmon and resonator. Subsequently, a packaged 3-D chip comprising 24 floating transmons is demonstrated. The transmission spectrum is measured, with all readout resonators successfully located at their designated positions on the spectrum. Two-tone spectroscopy is demonstrated, enabling precise measurement of the qubit frequency.",

keywords = "Flip-chip integration, quantum measurement, qubit modeling, superconducting qubit, transmon, two-level system (TLS) losses",

author = "Zhen Luo and Thomas Mayer and Daniela Zahn and \{Moran Guizan\}, Carla and Johannes Weber and Simon Lang and Hannes Bender and Luis Schwarzenbach and Lars Nebrich and Rui Pereira and Amelie Hagelauer",

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Luo, Z, Mayer, T, Zahn, D, Moran Guizan, C, Weber, J, Lang, S, Bender, H, Schwarzenbach, L, Nebrich, L, Pereira, R & Hagelauer, A 2025, 'A Demonstration of Multifloating Superconducting Qubits on a 3-D Flip-Chip Platform With TLS Loss Mitigation via Apertures', IEEE Microwave and Wireless Technology Letters, vol. 35, no. 6, pp. 832-835. https://doi.org/10.1109/LMWT.2025.3559221

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AU - Luo, Zhen

AU - Mayer, Thomas

AU - Zahn, Daniela

AU - Moran Guizan, Carla

AU - Weber, Johannes

AU - Lang, Simon

AU - Bender, Hannes

AU - Schwarzenbach, Luis

AU - Nebrich, Lars

AU - Pereira, Rui

AU - Hagelauer, Amelie

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Y1 - 2025

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AB - Flip-chip platforms are among the most promising approaches for scaling up superconducting qubits in quantum computing. This work presents the design, modeling, and analysis of floating transmon qubits implemented on a 3-D flip-chip platform. A major focus during qubit design is addressing coherence challenges caused by two-level system (TLS) losses, particularly from surface interfaces. TLS losses at the metal-air (MA) interface are mitigated by introducing apertures beneath the qubit pads. The aperture size is optimized to balance two key factors: minimizing total TLS loss and ensuring sufficient coupling strength between the transmon and resonator. Subsequently, a packaged 3-D chip comprising 24 floating transmons is demonstrated. The transmission spectrum is measured, with all readout resonators successfully located at their designated positions on the spectrum. Two-tone spectroscopy is demonstrated, enabling precise measurement of the qubit frequency.

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KW - quantum measurement

KW - qubit modeling

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KW - transmon

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A Demonstration of Multifloating Superconducting Qubits on a 3-D Flip-Chip Platform With TLS Loss Mitigation via Apertures

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