Synchronized High-Fidelity Two-Qubit Gates in Double Quantum Dots

ORAL

Abstract

While single-qubit gates with fidelities exceeding 99% for spin qubits in natural silicon and 99.9% in isotopically purified silicon have been demonstrated [1], the fidelity of two-qubit gates is still subject to several limitations. Motivated by recent experiments [2], we theoretically describe a high-fidelity controlled-NOT gate using the exchange interaction between the spins in neighboring quantum dots subject to a magnetic field gradient. We find an optimal gate sequence and present a synchronization method which avoids detrimental spin flips when the control qubit is in state 0. Furthermore, we identify systematic phase mismatches accumulated during the gate. We show that by synchronizing the resonant and off-resonant transitions and compensating unintended phases, the overall gate fidelity can be increased significantly. Numerical simulations also demonstrate a high tolerance against charge noise due to a partial intrinsic refocussing mechanism.

[1] J. Yoneda et al., arXiv:1708.01454.
[2] D. M. Zajac, A. J. Sigillito, M. Russ, F. Borjans, J. M. Taylor, G. Burkard, and J. R. Petta, arXiv:1708.03530.

*Funded by the Army Research Office through Grant No. W911NF-15-1-0149.

Presenters

  • Guido Burkard

    • University of Konstanz
    • Physics, University of Konstanz
    • Department of Physics, University of Konstanz
    • Univ Konstanz
    • Uni Konstanz
    • Physics, Univ. Konstanz
    • Physics, Univ Konstanz

Authors

  • Guido Burkard

    • University of Konstanz
    • Physics, University of Konstanz
    • Department of Physics, University of Konstanz
    • Univ Konstanz
    • Uni Konstanz
    • Physics, Univ. Konstanz
    • Physics, Univ Konstanz

  • Maximilian Russ

    • Physics, University of Konstanz
    • Physics, Univ. Konstanz

  • Jacob Taylor

    • Joint Quantum Institute and Joint Center for Quantum information Processing and Computer Science, NIST and University of Maryland
    • Joint Quantum Institute/NIST
    • National Institute of Standards and Technology
    • JQI/NIST
    • JQI, NIST & Univ. Maryland
    • Joint Center for Quantum Information and Computer Science, University of Maryland
    • Joint Quantum Institute

  • David Zajac

    • Physics, Princeton University
    • Physics, Princeton Univ.
    • Department of Physics, Princeton University

  • Anthony Sigillito

    • Physics, Princeton University
    • Princeton Univ
    • Physics, Princeton Univ.

  • Felix Borjans

    • Physics, Princeton Univ.
    • Department of Physics, Princeton University

  • Jason Petta

    • Physics, Princeton University
    • Princeton University
    • Department of Physics, Princeton University
    • Physics, Princeton Univ.