| Autor: |
Jin, X. Y., Cicak, K., Parrott, Z., Kotler, S., Lecocq, F., Teufel, J., Aumentado, J., Kapit, E., Simmonds, R. W. |
| Rok vydání: |
2023 |
| Předmět: |
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| DOI: |
10.48550/arxiv.2305.02907 |
| Popis: |
Parametric coupling is a powerful technique for generating tunable interactions between superconducting circuits using only microwave tones. Here, we present a highly flexible parametric coupling scheme demonstrated with two transmon qubits, which can be employed for multiple purposes, including the removal of residual $ZZ$ coupling and the implementation of driven swap or swap-free controlled-$Z$ (c$Z$) gates. Our fully integrated coupler design is only weakly flux tunable, cancels static linear coupling between the qubits, avoids internal coupler dynamics or excitations, and operates with rf-pulses. We show that residual $ZZ$ coupling can be reduced with a parametric dispersive tone down to an experimental uncertainty of 5.5 kHz. Additionally, randomized benchmarking reveals that the parametric swap c$Z$ gate achieves a fidelity of 99.4% in a gate duration of 60 ns, while the dispersive parametric swap-free c$Z$ gate attains a fidelity of 99.5% in only 30 ns. We believe this is the fastest and highest fidelity gate achieved with on-chip parametric coupling to date. We further explore the dependence of gate fidelity on gate duration for both p-swap and p-swap-free c$Z$ gates, providing insights into the possible error sources for these gates. Overall, our findings demonstrate a versatility, precision, speed, and high performance not seen in previous parametric approaches. Finally, our design opens up new possibilities for creating larger, modular systems of superconducting qubits. |
| Databáze: |
OpenAIRE |
| Externí odkaz: |
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