Related papers: Experimental setup for the combined study of spin ensembles and superconducting quantum circuits

Experimental setup for the combined study of spin ensembles and superconducting quantum circuits

URL: http://arxiv.org/abs/2602.11739v1
Date: Thu, 12 Feb 2026 09:05:40 GMT
Title: Experimental setup for the combined study of spin ensembles and superconducting quantum circuits
Authors: Lukas Vogl, Gerhard B. P. Huber, Ana Strinić, Achim Marx, Stefan Filipp, Kirill G. Fedorov, Rudolf Gross, Nadezhda P. Kukharchyk,
Abstract summary: Superconducting qubits are highly sensitive to magnetic fields, while spin ensembles require finite fields for control.<n>In this work, we demonstrate the first experimental setup that satisfies these constraints and provides verified qubit stability.<n>We show that several layers of Cryophy shielding and an additional superconducting aluminum shield suppress magnetic crosstalk by more than eight orders of magnitude.
Score: 0.0691846388904816
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: A hybrid quantum computing architecture combining quantum processors and quantum memory units allows for exploiting each component's unique properties to enhance the overall performance of the total system. However, superconducting qubits are highly sensitive to magnetic fields, while spin ensembles require finite fields for control, creating a major integration challenge. In this work, we demonstrate the first experimental setup that satisfies these constraints and provides verified qubit stability. Our cryogenic setup comprises two spatially and magnetically decoupled sample volumes inside a single dilution refrigerator: one hosting flux-tunable superconducting qubits and the other a spin ensemble equipped with a superconducting solenoid generating fields up to 50 mT. We show that several layers of Cryophy shielding and an additional superconducting aluminum shield suppress magnetic crosstalk by more than eight orders of magnitude, ensuring stability of the qubit's performance. Moreover, the operation of the solenoid adds minimal thermal load on the relevant stages of the dilution refrigerator. Our results enable scalable hybrid quantum architectures with low-loss integration, marking a key step toward scalable hybrid quantum computing platforms.

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