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This study presents the design, simulation, and experimental characterization of a superconducting transmon qubit circuit prototype for potential applications in dark matter detection experiments. We describe a planar circuit design featuring two non-interacting transmon qubits, one with fixed frequency and the other flux tunable. Finite-element simulations were employed to extract key Hamiltonian parameters and optimize component geometries. The qubit was fabricated and then characterized at 20 mK, allowing for a comparison between simulated and measured qubit parameters. Good agreement was found for transition frequencies and anharmonicities (within 1% and 10% respectively) while coupling strengths exhibited larger discrepancies (30%). We discuss potential causes for measured coherence times falling below expectations (T1 ∼1-2 μs) and propose strategies for future design improvements. Notably, we demonstrate the application of a hybrid 3D-2D simulation approach for energy participation ratio evaluation, yielding a more accurate estimation of dielectric losses. This work represents an important first step in developing planar Quantum Non-Demolition (QND) single-photon counters for dark matter searches, particularly for axion and dark photon detection schemes.

Transmon qubit modeling and characterization for Dark Matter search / R. Moretti, D. Labranca, P. Campana, R. Carobene, M. Gobbo, M.A. Castellanos-Beltran, D. Olaya, P.F. Hopkins, L. Banchi, M. Borghesi, A. Candido, S. Carrazza, H.A. Corti, A. D'Elia, M. Faverzani, E. Ferri, A. Nucciotti, L. Origo, A. Pasquale, A.S.P. Komnang, A. Rettaroli, S. Tocci, C. Gatti, A. Giachero. - In: IEEE TRANSACTIONS ON QUANTUM ENGINEERING. - ISSN 2689-1808. - (2025), pp. 1-9. [10.1109/tqe.2025.3633176]

Transmon qubit modeling and characterization for Dark Matter search

S. Carrazza;A. Pasquale;
2025

Abstract

This study presents the design, simulation, and experimental characterization of a superconducting transmon qubit circuit prototype for potential applications in dark matter detection experiments. We describe a planar circuit design featuring two non-interacting transmon qubits, one with fixed frequency and the other flux tunable. Finite-element simulations were employed to extract key Hamiltonian parameters and optimize component geometries. The qubit was fabricated and then characterized at 20 mK, allowing for a comparison between simulated and measured qubit parameters. Good agreement was found for transition frequencies and anharmonicities (within 1% and 10% respectively) while coupling strengths exhibited larger discrepancies (30%). We discuss potential causes for measured coherence times falling below expectations (T1 ∼1-2 μs) and propose strategies for future design improvements. Notably, we demonstrate the application of a hybrid 3D-2D simulation approach for energy participation ratio evaluation, yielding a more accurate estimation of dielectric losses. This work represents an important first step in developing planar Quantum Non-Demolition (QND) single-photon counters for dark matter searches, particularly for axion and dark photon detection schemes.
Quantum Circuit; Quantum Sensing; Qubit Characterization; Qubit Design; Qubit Simulation; Transmon;
Settore PHYS-03/A - Fisica sperimentale della materia e applicazioni
Settore PHYS-04/A - Fisica teorica della materia, modelli, metodi matematici e applicazioni
2025
14-nov-2025
https://ieeexplore.ieee.org/document/11249713
Article (author)
01 - Articolo su periodico
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/2434/1196575
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