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Universal high-fidelity quantum gates for spin-qubits in diamond (2403.10633v1)

Published 15 Mar 2024 in quant-ph and cond-mat.mes-hall

Abstract: Spins associated to solid-state colour centers are a promising platform for investigating quantum computation and quantum networks. Recent experiments have demonstrated multi-qubit quantum processors, optical interconnects, and basic quantum error correction protocols. One of the key open challenges towards larger-scale systems is to realize high-fidelity universal quantum gates. In this work, we design and demonstrate a complete high-fidelity gate set for the two-qubit system formed by the electron and nuclear spin of a nitrogen-vacancy center in diamond. We use gate set tomography (GST) to systematically optimise the gates and demonstrate single-qubit gate fidelities of up to $99.999(1)\%$ and a two-qubit gate fidelity of $99.93(5) \%$. Our gates are designed to decouple unwanted interactions and can be extended to other electron-nuclear spin systems. The high fidelities demonstrated provide new opportunities towards larger-scale quantum processing with colour-center qubits.

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References (14)
  1. J. Zhang, S. S. Hegde, and D. Suter, Efficient implementation of a quantum algorithm in a single nitrogen-vacancy center of diamond, Phys. Rev. Lett. 125, 030501 (2020).
  2. E. Knill, Quantum computing with realistically noisy devices, Nature 434, 39 (2005).
  3. P. Aliferis, D. Gottesman, and J. Preskill, Quantum accuracy threshold for concatenated distance-3 codes, Quantum Info. Comput. 6, 97–165 (2006).
  4. B. M. Terhal, Quantum error correction for quantum memories, Rev. Mod. Phys. 87, 307 (2015).
  5. G. White, C. Hill, and L. Hollenberg, Performance optimization for drift-robust fidelity improvement of two-qubit gates, Phys. Rev. Appl. 15, 014023 (2021).
  6. J. Emerson, R. Alicki, and K. Życzkowski, Scalable noise estimation with random unitary operators, Journal of Optics B: Quantum and Semiclassical Optics 7, S347 (2005).
  7. E. Magesan, R. Blume-Kohout, and J. Emerson, Gate fidelity fluctuations and quantum process invariants, Phys. Rev. A 84, 012309 (2011).
  8. J. J. Wallman and S. T. Flammia, Randomized benchmarking with confidence, New Journal of Physics 16, 103032 (2014).
  9. Y.-X. Liu, A. Ajoy, and P. Cappellaro, Nanoscale vector dc magnetometry via ancilla-assisted frequency up-conversion, Phys. Rev. Lett. 122, 100501 (2019).
  10. M. A. Nielsen, A simple formula for the average gate fidelity of a quantum dynamical operation, Physics Letters A 303, 249 (2002).
  11. Y. R. Sanders, J. J. Wallman, and B. C. Sanders, Bounding quantum gate error rate based on reported average fidelity, New Journal of Physics 18, 012002 (2015).
  12. O. Kern, G. Alber, and D. L. Shepelyansky, Quantum error correction of coherent errors by randomization, The European Physical Journal D 32, 153–156 (2005).
  13. J. J. Wallman and J. Emerson, Noise tailoring for scalable quantum computation via randomized compiling, Physical Review A 94, 10.1103/physreva.94.052325 (2016).
  14. Delft High Performance Computing Centre (DHPC), DelftBlue Supercomputer (Phase 1), https://www.tudelft.nl/dhpc/ark:/44463/DelftBluePhase1 (2023).
Citations (10)
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