Title :
High-Q whispering modes in empty spherical cavity resonators
Author :
Tobar, Michael E. ; Anstie, James D. ; Hartnett, John G.
Author_Institution :
Dept. of Phys., Western Australia Univ., Crawley, WA, Australia
Abstract :
This work presents the study of high-order modes in spherical cavity resonators. In general there are resonant mode families, degenerate in frequency, that "whisper" around the spherical surface. We call these whispering spherical (WS) mode sets. Each set includes the well-known whispering gallery (WG) mode, which propagates like a ray around the azimuth. Also, we identify a new mode, which we label the whispering longitudinal (WL) mode. This mode propagates as a wave front along the longitudinal direction. The rest of the degenerate set propagates like a combination of the WG and WL modes. We show that transverse electric WS modes have high geometric factors, greater than 2000, which increase linearly with frequency. This is an order of magnitude greater than that of a TM/sub 010/ cylindrical resonator. Also, Q-factors as high as 65,000 at 13.3 GHz were measured at room temperature.
Keywords :
Q-factor; cavity resonator filters; contact resistance; surface resistance; 13.3 GHz; 293 to 298 K; Q factors; TM/sub 010/ cylindrical resonator; degenerate set propagation; geometric factors; high Q whispering modes; high order modes; longitudinal direction; resonant mode; room temperature; spherical cavity resonators; spherical surface; transverse electric whispering spherical modes; whispering gallery; whispering longitudinal mode; Azimuth; Cavity resonators; Frequency; Magnetic resonance; Magnetic separation; Maxwell equations; Q factor; Resonator filters; Tellurium; Temperature measurement;
Journal_Title :
Ultrasonics, Ferroelectrics, and Frequency Control, IEEE Transactions on
DOI :
10.1109/TUFFC.2003.1251123
