| Home > Publications database > Experimental error suppression in Cross-Resonance gates via multi-derivative pulse shaping |
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| APC | 3000.00 | 0.00 | EUR | 93.80 % | (Zahlung erfolgt) | ZB |
| APC | 198.15 | 0.00 | EUR | 6.20 % | (Zahlung angewiesen) | |
| Sum | 3198.15 | 0.00 | EUR | |||
| Total | 3198.15 |
| Journal Article | FZJ-2024-07358 |
; ;
2024
Nature Publ. Group
London
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Please use a persistent id in citations: doi:10.1038/s41534-024-00863-4 doi:10.34734/FZJ-2024-07358
Abstract: While quantum circuits are reaching impressive widths in the hundreds of qubits, their depths have not been able to keep pace. In particular, cloud computing gates on multi-qubit, fixed-frequency superconducting chips continue to hover around the 1% error range, contrasting with the progress seen on carefully designed two-qubit chips, where error rates have been pushed towards 0.1%. Despite the strong impetus and a plethora of research, experimental demonstration of error suppression on these multi-qubit devices remains challenging, primarily due to the wide distribution of qubit parameters and the demanding calibration process required for advanced control methods. Here, we achieve this goal, using a simple control method based on multi-derivative, multi-constraint pulse shaping, which acts simultaneously against multiple error sources. Our approach establishes a two to fourfold improvement on the default calibration scheme, demonstrated on four qubits on the IBM Quantum Platform with limited and intermittent access, enabling these large-scale fixed-frequency systems to fully take advantage of their superior coherence times. The achieved CNOT fidelities of 99.7(1)% on those publically available qubits come from both coherent control error suppression and accelerated gate time.
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