Quantum Sensing is a rapidly expanding research field that finds one of its applications in Fundamental Physics, as the search for Dark Matter. Devices based on superconducting qubits have already been successfully applied in detecting few-GHz single photons via Quantum Non-Demolition measurement (QND). This technique allows us to perform repeatable measurements, bringing remarkable sensitivity improvements and dark count rate suppression in experiments based on high-precision microwave photon detection, such as for Axions and Dark Photons search. In this context, the INFN Qub-IT project goal is to realize an itinerant single-photon counter based on superconducting qubits that will exploit QND for enhancing Axion search experiments. In this study, we present Qub-IT's status towards the realization of its first superconducting qubit device, illustrating design and simulation procedures and the characterization of fabricated Coplanar Waveguide Resonators (CPWs) for readout. We match target qubit parameters and assess a few-percent level agreement between lumped and distributed element simulation models. We reach a maximum internal quality factor of 9.2×105 for -92 dBm on-chip readout power.

Moretti, R., Corti, H., Labranca, D., Ahrens, F., Avallone, G., Babusci, D., et al. (2024). Design and Simulation of a Transmon Qubit Chip for Axion Detection. IEEE TRANSACTIONS ON APPLIED SUPERCONDUCTIVITY, 34(3), 1-5 [10.1109/TASC.2024.3350582].

Design and Simulation of a Transmon Qubit Chip for Axion Detection

Moretti R.;Corti H. A.;Labranca D.;Borghesi M.;Fanciulli M.;Faverzani M.;Ferri E.;Giachero A.;Nucciotti A.;Origo L.;Sanguinetti S.;
2024

Abstract

Quantum Sensing is a rapidly expanding research field that finds one of its applications in Fundamental Physics, as the search for Dark Matter. Devices based on superconducting qubits have already been successfully applied in detecting few-GHz single photons via Quantum Non-Demolition measurement (QND). This technique allows us to perform repeatable measurements, bringing remarkable sensitivity improvements and dark count rate suppression in experiments based on high-precision microwave photon detection, such as for Axions and Dark Photons search. In this context, the INFN Qub-IT project goal is to realize an itinerant single-photon counter based on superconducting qubits that will exploit QND for enhancing Axion search experiments. In this study, we present Qub-IT's status towards the realization of its first superconducting qubit device, illustrating design and simulation procedures and the characterization of fabricated Coplanar Waveguide Resonators (CPWs) for readout. We match target qubit parameters and assess a few-percent level agreement between lumped and distributed element simulation models. We reach a maximum internal quality factor of 9.2×105 for -92 dBm on-chip readout power.
Articolo in rivista - Articolo scientifico
Coplanar waveguides; Couplings; CPW characterization; Dispersion; Photonics; quantum sensing; Qubit; qubit design; qubit simulation; Resonators; Superconducting microwave devices; X-mon;
English
19-gen-2024
2024
34
3
1
5
none
Moretti, R., Corti, H., Labranca, D., Ahrens, F., Avallone, G., Babusci, D., et al. (2024). Design and Simulation of a Transmon Qubit Chip for Axion Detection. IEEE TRANSACTIONS ON APPLIED SUPERCONDUCTIVITY, 34(3), 1-5 [10.1109/TASC.2024.3350582].
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/10281/458563
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