Title :
Optical mapping of surface vibrations on a thin-film resonator near 2 GHz
Author :
Graebner, J.E. ; Safar, H.F. ; Barber, B. ; Gammel, P.L. ; Herbsommer, J. ; Fetter, L.A. ; Pastalan, J. ; Huggins, H.A. ; Miller, R.E.
Author_Institution :
Lucent Technol. Bell Labs., Murray Hill, NJ, USA
Abstract :
An optical scanning interferometer is used to examine the mode structure of a solidly-mounted thin-film resonator (TFR) when it is excited electrically in the neighborhood of its resonant frequency. Scans across the surface with <1 μm lateral resolution and 0.3 pm (0.003 Angstrom) vertical resolution reveal a rich spectrum of modes. At the mechanical resonance a uniform up-and-down motion is observed, while at slightly higher frequencies near the pole frequency the mode pattern breaks up into standing waves with wavelengths ranging from 10-100 μm. A second set of standing waves with discrete wavelengths in the range 2-5 μm and with random orientation is observed over a broader frequency range. Semi-quantitative agreement is found between the data and the dispersion curves calculated with a transfer matrix technique for the multilayer waveguide structure of the TFR
Keywords :
crystal resonators; light interferometry; surface dynamics; thin film devices; 2 GHz; dispersion curve; mechanical resonance; mode structure; multilayer waveguide; optical scanning interferometric mapping; pole frequency; resonant frequency; standing wave; surface vibration; thin film resonator; transfer matrix; Nonhomogeneous media; Optical films; Optical interferometry; Optical resonators; Optical surface waves; Optical waveguides; Resonance; Resonant frequency; Transmission line matrix methods; Vibrations;
Conference_Titel :
Ultrasonics Symposium, 2000 IEEE
Conference_Location :
San Juan
Print_ISBN :
0-7803-6365-5
DOI :
10.1109/ULTSYM.2000.922628
