Phase-modulated decoupling and error suppression in qubit-oscillator systems
Abstract
We present a scheme designed to suppress the dominant source of infidelity in entangling gates between quantum systems coupled through intermediate bosonic oscillator modes. Such systems are particularly susceptible to residual qubit-oscillator entanglement at the conclusion of a gate period which reduces the fidelity of the target entangling operation. We demonstrate how the exclusive use of discrete phase shifts in the field moderating the qubit-oscillator interaction - easily implemented with modern synthesizers - is sufficient to both ensure multiple oscillator modes are decoupled and to suppress the effects of fluctuations in the driving field. This approach is amenable to a wide variety of technical implementations including geometric phase gates in superconducting qubits and the Molmer-Sorensen gate for trapped ions. We present detailed example protocols tailored to trapped-ion experiments and demonstrate that our approach allows multiqubit gate implementation with a significant reduction in technical complexity relative to previously demonstrated protocols.
Keywords
Cite
@article{arxiv.1408.2749,
title = {Phase-modulated decoupling and error suppression in qubit-oscillator systems},
author = {T. J. Green and M. J. Biercuk},
journal= {arXiv preprint arXiv:1408.2749},
year = {2015}
}
Comments
Related manuscripts available at http://www.physics.usyd.edu.au/~mbiercuk/Publications.html