Optimal tuning of solid-state quantum gates: A universal two-qubit gate

E. Paladino; A. Mastellone; A. D'Arrigo; G. Falci

doi:10.1103/PhysRevB.81.052502

Optimal tuning of solid-state quantum gates: A universal two-qubit gate

Mesoscale and Nanoscale Physics 2010-02-16 v2 Superconductivity

Authors: E. Paladino , A. Mastellone , A. D'Arrigo , G. Falci

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Abstract

We present a general route to reduce inhomogeneous broadening in nanodevices due to 1/f noise. We apply this method to a universal two-qubit gate and demonstrate that for selected optimal couplings, a high-efficient gate can be implemented even in the presence of 1/f noise. Entanglement degradation due to interplay of 1/f and quantum noise is quantified via the concurrence. A charge-phase $\sqrt{{\rm i-SWAP}}$ gate for spectra extrapolated from single qubit experiments is analyzed.

Keywords

quantum gates and qubits quantum noise quantum decoherence in superconducting qubits

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@article{arxiv.0906.3115,
  title  = {Optimal tuning of solid-state quantum gates: A universal two-qubit gate},
  author = {E. Paladino and A. Mastellone and A. D'Arrigo and G. Falci},
  journal= {arXiv preprint arXiv:0906.3115},
  year   = {2010}
}

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Replaced with published version. Modified manuscript

Optimal tuning of solid-state quantum gates: A universal two-qubit gate

Abstract

Keywords

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