Normal Metal Quasiparticle Traps in 3D-Transmon Qubits
ORAL
Abstract
Quasiparticles are a known source of decoherence in Josephson-junction based superconducting qubits. While equilibrium quasiparticles should not be present in devices operated at dilution refrigeration temperatures well below the superconducting energy gap, non-thermal quasiparticles have been observed in many different superconducting qubits, including 3D-transmons and fluxonium qubits. Vortices induced by applied magnetic fields have been shown to improve non-equilibrium quasiparticle decay rates and improve coherence times by creating regions of the superconductor with vanishing energy gap, which act as quasiparticle traps. We aim to further mitigate quasiparticle-induced limits on coherence by engineering strong trapping via the introduction of normal metal to the superconducting qubit. In this talk, we present recent results regarding normal metal quasiparticle traps in 3D-transmon qubits.
*Work supported by ARO, A*STAR
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Authors
L.D. Burkhart
Department of Applied Physics and Physics, Yale University
Department of Physics and Applied Physics, Yale University, New Haven, Connecticut
Yvonne Y. Gao
Department of Applied Physics, Yale University
Department of Applied Physics and Physics, Yale University
Yale University
Chen Wang
Department of Applied Physics, Yale University
Department of Applied Physics and Physics, Yale University
Yale University
Kyle Serniak
Department of Applied Physics, Yale University
Department of Applied Physics and Physics, Yale University
Gijs de Lange
Department of Applied Physics, Yale University
Department of Applied Physics and Physics, Yale University
Yiwen Chu
Yale University
Department of Applied Physics and Physics, Yale University
Uri Vool
Department of Applied Physics, Yale University
Department of Applied Physics and Physics, Yale University
L. Frunzio
Yale University
Department of Applied Physics, Yale University
Department of Applied Physics and Physics, Yale University
Yale University, Department of Applied Physics
Yale University Department of Applied Physics
M. H. Devoret
Yale University
Department of Applied Physics, Yale University
Yale Univesity
Department of Applied Physics and Physics, Yale University
Yale University, Department of Applied Physics
Yale University Department of Applied Physics
Gianluigi Catelani
Peter Grunberg Institut (PGI-2), Forschungszentrum Julich
Leonid Glazman
Department of Applied Physics, Yale University
Department of Applied Physics and Physics, Yale University
Yale University
Department of Physics, Yale University
R. J. Schoekopf
Yale University
Department of Applied Physics, Yale University
Department of Applied Physics and Physics, Yale University
Department of Physics and Applied Physics, Yale University, New Haven, Connecticut
Departments of Applied Physics and Physics, Yale University, New Haven, Connecticut, USA.
