Improving the Coherence Time of Microwave Cavities

Matthew Reagor; Hanhee Paik; Luyan Sun; Eric Holland; Luigi Frunzio; Robert Schoelkopf

Improving the Coherence Time of Microwave Cavities

ORAL

Abstract

A superconducting cavity resonator is able to store quantum states of light, protect qubits from decoherence and place bounds on material losses. The resonator's utility in all three goals is inherently tied to its quality factor. We report recent progress in improving the quality factors of aluminum waveguide cavities in the quantum regime. We will also report on the use of these cavities to measure the dielectric properties of low-loss substrates and the surface impedance of bulk superconductors and thin films.

Feb. 28, 2012, 5:06 PM – Feb. 28, 2012, 5:18 PM

Authors

Matthew Reagor
- Yale University
- Department of Physics and Applied Physics, Yale University
Hanhee Paik
- Yale University
- Department of Physics and Applied Physics, Yale University
- Applied Physics Department Yale University
Luyan Sun
- Yale University
- Department of Physics and Applied Physics, Yale University
Eric Holland
- Yale University
- Department of Physics and Applied Physics, Yale University
Luigi Frunzio
- Applied Physics Department, Yale University
- Yale University
- Department of Physics and Applied Physics, Yale University
- Applied Physics Department Yale University
- Applied Physics - Yale University
- Yale University, Dept. of Applied Physics
- Department of Applied Physics, Yale University
Robert Schoelkopf
- Yale University
- Department of Physics and Applied Physics, Yale University
- Applied Physics Department Yale University