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Main Authors: Yao, Zhancheng, Fuhr, Nicholas E., Russo, Nicholas, Abraham, David W., Smith, Kevin E., Bishop, David J.
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2603.09096
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author Yao, Zhancheng
Fuhr, Nicholas E.
Russo, Nicholas
Abraham, David W.
Smith, Kevin E.
Bishop, David J.
author_facet Yao, Zhancheng
Fuhr, Nicholas E.
Russo, Nicholas
Abraham, David W.
Smith, Kevin E.
Bishop, David J.
contents Modular architectures are a promising route toward scalable superconducting quantum processors, but finite fabrication yield and the lack of high quality temporary interconnects impose fundamental limitations on system size. Here, we demonstrate chip-scale liquid-metal interconnects that show promise for plug-and-play superconducting quantum circuits by enabling non-destructive module replacement while maintaining high microwave performance. Using gallium-based liquid metals, we realize high-quality inter-module signal and ground interconnects, comparable in performance to conventional coplanar waveguide resonators. We illustrate consistent device characteristics across three thermal cycles between room temperature and 15 mK, as well as the ability to reform superconducting connections following module replacement. A width-dependent resonance frequency shift reveals a significant kinetic inductance fraction, which we attribute to the presence of $β$-phase tantalum as confirmed by X-ray characterization. Finally, we investigate power-dependent loss mechanisms and observe high-power dissipative nonlinearities qualitatively consistent with a readout-power heating model. These results establish liquid metals as viable chip-scale interconnects for reconfigurable, modular superconducting quantum systems.
format Preprint
id arxiv_https___arxiv_org_abs_2603_09096
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Reconfigurable Superconducting Quantum Circuits Enabled by Micro-Scale Liquid-Metal Interconnects
Yao, Zhancheng
Fuhr, Nicholas E.
Russo, Nicholas
Abraham, David W.
Smith, Kevin E.
Bishop, David J.
Quantum Physics
Materials Science
Modular architectures are a promising route toward scalable superconducting quantum processors, but finite fabrication yield and the lack of high quality temporary interconnects impose fundamental limitations on system size. Here, we demonstrate chip-scale liquid-metal interconnects that show promise for plug-and-play superconducting quantum circuits by enabling non-destructive module replacement while maintaining high microwave performance. Using gallium-based liquid metals, we realize high-quality inter-module signal and ground interconnects, comparable in performance to conventional coplanar waveguide resonators. We illustrate consistent device characteristics across three thermal cycles between room temperature and 15 mK, as well as the ability to reform superconducting connections following module replacement. A width-dependent resonance frequency shift reveals a significant kinetic inductance fraction, which we attribute to the presence of $β$-phase tantalum as confirmed by X-ray characterization. Finally, we investigate power-dependent loss mechanisms and observe high-power dissipative nonlinearities qualitatively consistent with a readout-power heating model. These results establish liquid metals as viable chip-scale interconnects for reconfigurable, modular superconducting quantum systems.
title Reconfigurable Superconducting Quantum Circuits Enabled by Micro-Scale Liquid-Metal Interconnects
topic Quantum Physics
Materials Science
url https://arxiv.org/abs/2603.09096