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Hauptverfasser: Schirk, Johannes, Wallner, Florian, Huang, Longxiang, Tsitsilin, Ivan, Bruckmoser, Niklas, Koch, Leon, Bunch, David, Glaser, Niklas J., Huber, Gerhard B. P., Knudsen, Martin, Krylov, Gleb, Marx, Achim, Pfeiffer, Frederik, Richard, Lea, Roy, Federico A., Romeiro, João H., Singh, Malay, Södergren, Lasse, Dionis, Etienne, Sugny, Dominique, Werninghaus, Max, Liegener, Klaus, Schneider, Christian M. F., Filipp, Stefan
Format: Preprint
Veröffentlicht: 2024
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2410.00495
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author Schirk, Johannes
Wallner, Florian
Huang, Longxiang
Tsitsilin, Ivan
Bruckmoser, Niklas
Koch, Leon
Bunch, David
Glaser, Niklas J.
Huber, Gerhard B. P.
Knudsen, Martin
Krylov, Gleb
Marx, Achim
Pfeiffer, Frederik
Richard, Lea
Roy, Federico A.
Romeiro, João H.
Singh, Malay
Södergren, Lasse
Dionis, Etienne
Sugny, Dominique
Werninghaus, Max
Liegener, Klaus
Schneider, Christian M. F.
Filipp, Stefan
author_facet Schirk, Johannes
Wallner, Florian
Huang, Longxiang
Tsitsilin, Ivan
Bruckmoser, Niklas
Koch, Leon
Bunch, David
Glaser, Niklas J.
Huber, Gerhard B. P.
Knudsen, Martin
Krylov, Gleb
Marx, Achim
Pfeiffer, Frederik
Richard, Lea
Roy, Federico A.
Romeiro, João H.
Singh, Malay
Södergren, Lasse
Dionis, Etienne
Sugny, Dominique
Werninghaus, Max
Liegener, Klaus
Schneider, Christian M. F.
Filipp, Stefan
contents Protecting qubits from environmental noise while maintaining strong coupling for fast high-fidelity control is a central challenge for quantum information processing. Here, we demonstrate a control scheme for superconducting fluxonium qubits that eliminates qubit decay through the control channel by suppressing the environmental density of states at the transition frequency. Adding a low-pass filter on the flux line allows for flux-biasing and, at the same time, coherently controlling the fluxonium qubit by parametrically driving it at integer fractions of its transition frequency. We compare the filtered to the unfiltered configuration and find a five times longer $T_1$, and ten times improved $T_2$-echo time in the filtered case. We demonstrate coherent control with up to 11-photon sub-harmonic drives, highlighting the strong non-linearity of the fluxonium potential. Measured Rabi frequencies and drive-induced frequency shifts show excellent agreement with numerical and analytical models. Furthermore, we show the equivalence of a 3-photon sub-harmonic drive to an on-resonance drive by benchmarking sub-harmonic gate fidelities above 99.94$\,$%. These results open up a scalable path for full qubit control through a single Purcell-protected channel, providing strong suppression of control-induced decoherence and enabling wiring-efficient superconducting quantum processors.
format Preprint
id arxiv_https___arxiv_org_abs_2410_00495
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Sub-Harmonic Control of a Fluxonium Qubit via a Purcell-Protected Flux Line
Schirk, Johannes
Wallner, Florian
Huang, Longxiang
Tsitsilin, Ivan
Bruckmoser, Niklas
Koch, Leon
Bunch, David
Glaser, Niklas J.
Huber, Gerhard B. P.
Knudsen, Martin
Krylov, Gleb
Marx, Achim
Pfeiffer, Frederik
Richard, Lea
Roy, Federico A.
Romeiro, João H.
Singh, Malay
Södergren, Lasse
Dionis, Etienne
Sugny, Dominique
Werninghaus, Max
Liegener, Klaus
Schneider, Christian M. F.
Filipp, Stefan
Quantum Physics
Protecting qubits from environmental noise while maintaining strong coupling for fast high-fidelity control is a central challenge for quantum information processing. Here, we demonstrate a control scheme for superconducting fluxonium qubits that eliminates qubit decay through the control channel by suppressing the environmental density of states at the transition frequency. Adding a low-pass filter on the flux line allows for flux-biasing and, at the same time, coherently controlling the fluxonium qubit by parametrically driving it at integer fractions of its transition frequency. We compare the filtered to the unfiltered configuration and find a five times longer $T_1$, and ten times improved $T_2$-echo time in the filtered case. We demonstrate coherent control with up to 11-photon sub-harmonic drives, highlighting the strong non-linearity of the fluxonium potential. Measured Rabi frequencies and drive-induced frequency shifts show excellent agreement with numerical and analytical models. Furthermore, we show the equivalence of a 3-photon sub-harmonic drive to an on-resonance drive by benchmarking sub-harmonic gate fidelities above 99.94$\,$%. These results open up a scalable path for full qubit control through a single Purcell-protected channel, providing strong suppression of control-induced decoherence and enabling wiring-efficient superconducting quantum processors.
title Sub-Harmonic Control of a Fluxonium Qubit via a Purcell-Protected Flux Line
topic Quantum Physics
url https://arxiv.org/abs/2410.00495