Fast flux qubit gates on a heavy fluxonium

Helin Zhang; Srivatsan Chakram; Nathan D Earnest; Yao Lu; Ziwen Huang; Daniel Weiss; Jens Koch; David I Schuster

Fast flux qubit gates on a heavy fluxonium

ORAL

Abstract

A capacitively shunted fluxonium qubit has both long life time and coherence time at the half-flux sweet spot. However, the suppressed matrix elements and low transition frequency make it challenging to perform fast fluxon gates via charge coupling. Here, we present schemes for state initialization, fast single-qubit flux gates, and plasmon assisted readout for a fluxonium qubit, demonstrating the feasibility of controlling a superconducting qubit at background temperatures much higher than the operating frequency. This scheme improves the quantum control of fluxonium qubits, making it a strong candidate for quantum information processing. We additionally present schemes for fluxonium two-qubit gates without using lossier higher levels.

March 2, 2020, 2:39 PM – March 2, 2020, 2:51 PM

Presenters

Helin Zhang

University of Chicago

Authors

Helin Zhang

University of Chicago
Srivatsan Chakram

University of Chicago, Physics, University of Chicago
Nathan D Earnest

University of Chicago
Yao Lu

University of Chicago, The James Franck Institute and Department of Physics, The University of Chicago
Ziwen Huang

Northwestern University, Physics, Northwestern University
Daniel Weiss

Northwestern University, Physics, Northwestern University
Jens Koch

Northwestern University, Physics and Astronomy, Northwestern University, Department of Physics and Astronomy, Northwestern University, Physics, Northwestern University
David I Schuster

University of Chicago, Physics, University of Chicago, Department of Physics and the James Franck Institute, University of Chicago, The James Franck Institute and Department of Physics, University of Chicago, The James Franck Institute and Department of Physics, The University of Chicago