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Auteurs principaux: Huber, G. B. P., Roy, F. A., Koch, L., Tsitsilin, I., Schirk, J., Glaser, N. J., Bruckmoser, N., Schweizer, C., Romeiro, J., Krylov, G., Singh, M., Haslbeck, F. X., Knudsen, M., Marx, A., Pfeiffer, F., Schneider, C., Wallner, F., Bunch, D., Richard, L., Södergren, L., Liegener, K., Werninghaus, M., Filipp, S.
Format: Preprint
Publié: 2024
Sujets:
Accès en ligne:https://arxiv.org/abs/2403.02203
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author Huber, G. B. P.
Roy, F. A.
Koch, L.
Tsitsilin, I.
Schirk, J.
Glaser, N. J.
Bruckmoser, N.
Schweizer, C.
Romeiro, J.
Krylov, G.
Singh, M.
Haslbeck, F. X.
Knudsen, M.
Marx, A.
Pfeiffer, F.
Schneider, C.
Wallner, F.
Bunch, D.
Richard, L.
Södergren, L.
Liegener, K.
Werninghaus, M.
Filipp, S.
author_facet Huber, G. B. P.
Roy, F. A.
Koch, L.
Tsitsilin, I.
Schirk, J.
Glaser, N. J.
Bruckmoser, N.
Schweizer, C.
Romeiro, J.
Krylov, G.
Singh, M.
Haslbeck, F. X.
Knudsen, M.
Marx, A.
Pfeiffer, F.
Schneider, C.
Wallner, F.
Bunch, D.
Richard, L.
Södergren, L.
Liegener, K.
Werninghaus, M.
Filipp, S.
contents As systems for quantum computing keep growing in size and number of qubits, challenges in scaling the control capabilities are becoming increasingly relevant. Efficient schemes to simultaneously mediate coherent interactions between multiple quantum systems and to reduce decoherence errors can minimize the control overhead in next-generation quantum processors. Here, we present a superconducting qubit architecture based on tunable parametric interactions to perform two-qubit gates, reset, leakage recovery and to read out the qubits. In this architecture, parametrically driven multi-element couplers selectively couple qubits to resonators and neighbouring qubits, according to the frequency of the drive. We consider a system with two qubits and one readout resonator interacting via a single coupling circuit and experimentally demonstrate a controlled-Z gate with a fidelity of $98.30\pm 0.23 \%$, a reset operation that unconditionally prepares the qubit ground state with a fidelity of $99.80\pm 0.02 \%$ and a leakage recovery operation with a $98.5\pm 0.3 \%$ success probability. Furthermore, we implement a parametric readout with a single-shot assignment fidelity of $88.0\pm 0.4 \%$. These operations are all realized using a single tunable coupler, demonstrating the experimental feasibility of the proposed architecture and its potential for reducing the system complexity in scalable quantum processors.
format Preprint
id arxiv_https___arxiv_org_abs_2403_02203
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Parametric multi-element coupling architecture for coherent and dissipative control of superconducting qubits
Huber, G. B. P.
Roy, F. A.
Koch, L.
Tsitsilin, I.
Schirk, J.
Glaser, N. J.
Bruckmoser, N.
Schweizer, C.
Romeiro, J.
Krylov, G.
Singh, M.
Haslbeck, F. X.
Knudsen, M.
Marx, A.
Pfeiffer, F.
Schneider, C.
Wallner, F.
Bunch, D.
Richard, L.
Södergren, L.
Liegener, K.
Werninghaus, M.
Filipp, S.
Quantum Physics
As systems for quantum computing keep growing in size and number of qubits, challenges in scaling the control capabilities are becoming increasingly relevant. Efficient schemes to simultaneously mediate coherent interactions between multiple quantum systems and to reduce decoherence errors can minimize the control overhead in next-generation quantum processors. Here, we present a superconducting qubit architecture based on tunable parametric interactions to perform two-qubit gates, reset, leakage recovery and to read out the qubits. In this architecture, parametrically driven multi-element couplers selectively couple qubits to resonators and neighbouring qubits, according to the frequency of the drive. We consider a system with two qubits and one readout resonator interacting via a single coupling circuit and experimentally demonstrate a controlled-Z gate with a fidelity of $98.30\pm 0.23 \%$, a reset operation that unconditionally prepares the qubit ground state with a fidelity of $99.80\pm 0.02 \%$ and a leakage recovery operation with a $98.5\pm 0.3 \%$ success probability. Furthermore, we implement a parametric readout with a single-shot assignment fidelity of $88.0\pm 0.4 \%$. These operations are all realized using a single tunable coupler, demonstrating the experimental feasibility of the proposed architecture and its potential for reducing the system complexity in scalable quantum processors.
title Parametric multi-element coupling architecture for coherent and dissipative control of superconducting qubits
topic Quantum Physics
url https://arxiv.org/abs/2403.02203