Title :
Suppressing Fine-frequency modes in Aluminum Nitride microresonators
Author :
Branch, Darren W. ; Olsson, Roy H.
Author_Institution :
Biosensors & Nanomater. Dept., Sandia Nat. Labs., Albuquerque, NM, USA
Abstract :
Eliminating spurious modes in Aluminum Nitride (AlN) microresonators improves their insertion loss and quality factor by reducing acoustic energy leakage. Spurious modes that result from transverse wave propagation, termed fine-frequency modes, leak energy and propagate in the electrical busing and appear near the fundamental resonance. Although these modes can be predicted using three-dimensional (3D) finite element methods (FEM) for devices with very short acoustic length (e.g. 1 acoustic wavelength), 3D FEM is very slow and memory intensive when compared to a two-dimensional (2D) simulation. A fast 2D coupling-of-modes (COM) model was developed to predict, identify and implement strategies to suppress the fine-frequency modes.
Keywords :
III-V semiconductors; Q-factor; acoustic resonators; acoustic wave propagation; aluminium compounds; finite element analysis; micromechanical resonators; wide band gap semiconductors; 3D FEM; AlN; acoustic energy leakage; acoustic wavelength; aluminum nitride microresonators; fast 2D coupling-of-modes model; fine-frequency modes; quality factor; three-dimensional finite element methods; transverse wave propagation; Acoustics; Fingers; Finite element analysis; III-V semiconductor materials; Microcavities; Three-dimensional displays; Transducers; Aluminum nitride; COM; FEM; Lamb Waves; Spurious Modes;
Conference_Titel :
Ultrasonics Symposium (IUS), 2014 IEEE International
Conference_Location :
Chicago, IL
DOI :
10.1109/ULTSYM.2014.0141
