Spherical Bragg reflector resonators

Author

Tobar, Michael E. ; le Floch, Jean-Michel ; Cros, Dominique ; Krupka, Jerzy ; Anstie, James D. ; Hartnett, John G.

Author_Institution

Sch. of Phys., Western Australia Univ., Nedlands, WA, Australia

Volume

51

Issue

9

fYear

2004

Firstpage

1054

Lastpage

1059

Abstract

In this paper we introduce the concept of the spherical Bragg reflector (SBR) resonator. The resonator is made from multiple layers of spherical dielectric, loaded within a spherical cavity. The resonator is designed to concentrate the energy within the central region of the resonator and away from the cavity walls to minimize conductor losses. A set of simultaneous equations is derived, which allows the accurate calculation of the dimensions of the layers as well as the frequency. The solution is confirmed using finite-element analysis. A Teflon-free space resonator was constructed to prove the concept. The Teflon SBR was designed at 13.86 GHz and exhibited a Q-factor of 22,000, which agreed well with the design values. This represents a factor of 3.5 enhancement over a resonator limited by the loss-tangent of Teflon. Similarly, SBR resonators constructed with low-loss materials could achieve Q-factors of the order of 300,000.

Keywords

Q-factor; cavity resonators; dielectric losses; dielectric materials; dielectric resonators; finite element analysis; 13.86 GHz; Q-factor; conductor loss; finite element analysis; loss tangent; spherical Bragg reflector resonator; spherical cavity; spherical dielectric; teflon free space resonator; Conductors; Dielectric loss measurement; Dielectric materials; Dielectric measurements; Equations; Finite element methods; Frequency; Interference; Q factor; Surface resistance;

fLanguage

English

Journal_Title

Ultrasonics, Ferroelectrics, and Frequency Control, IEEE Transactions on

Publisher

ieee

ISSN

0885-3010

Type

jour

DOI

10.1109/TUFFC.2004.1334838

Filename

1334838