Title :
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
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;
Journal_Title :
Ultrasonics, Ferroelectrics, and Frequency Control, IEEE Transactions on
DOI :
10.1109/TUFFC.2004.1334838
