Title :
Microwave radiation force on a parallel-plate resonator
Author :
Makarov, S. ; Kulkarni, Santosh ; Berezin, A. ; Waldron, I.
Author_Institution :
Dept. of Electr. & Comput. Eng., Worcester Polytech. Inst., MA, USA
Abstract :
A simulation method is proposed and tested in order to determine the radiation force on metal targets, whose size is comparable to wavelength. The method is based on the MoM solution of the electric field integral equation, accurate calculation of the near fields, and removal of the self-interaction terms responsible for the pinch effect. The method is used to determine the local force distribution for a parallel-plate metal resonator and a circular disk resonator at plane wave incidence. It is observed that, at the resonance, the individual metal plates may experience very large local force densities, despite the fact that the net radiation force still remains very small.
Keywords :
dielectric resonators; electric field integral equations; electromagnetic forces; method of moments; micromechanical resonators; pinch effect; radiation; MoM solution; circular disk resonator; electric field integral equation; electromagnetic forces; local force densities; local force distribution; metal plates; metal targets; microresonators; microwave radiation force; moment methods; near fields calculation; parallel-plate resonator; pinch effect; plane wave incidence; resonance; self-interaction terms; Dielectric losses; Integral equations; Laser beams; Laser theory; Message-oriented middleware; Optical resonators; Optical scattering; Resonance light scattering; Symmetric matrices; Testing;
Conference_Titel :
Microwave Symposium Digest, 2004 IEEE MTT-S International
Print_ISBN :
0-7803-8331-1
DOI :
10.1109/MWSYM.2004.1339015
