Proceedings of the 45th Annual Symposium on Frequency Control,
pp. 77-101, 1991THE AGING OF BULK ACOUSTIC WAVE RESONATORS, FILTERS AND OSCILLATORS
John R. Vig* and Thrygve R. Meeker**
* U.S. Army Communications-Electronics Command
Research, Development & Engineering Center
Att: AMSEL-RD-C2-CS
Fort Monmouth, NJ 07703-5603
** 2956 Lindberg Ave.,
Allentown, PA 18103
TABLE OF CONTENTS
Contamination Transfer Effects: Adsorption, Desorption, Oxidation and Permeation.
Strain/Stress in the Resonator.
Temperature and Temperature-Cycling Dependence of Aging.
Frequency and Overtone Dependence of Aging.
Drive Level Dependence of Aging.
The Effects of Aging Interruptions.
Dependence of Aging on Material and Mode Type.
Dependence of Aging on Resonator Material.
Dependence of Aging on Mode Type.
Low-aging Oscillators: The State of the Art, Present and Future.
Multiple Aging Mechanism Pitfall.
Brief Review of the Theory of Rate Processes.
A Log-time Law of Chemisorption, Oxidation, and Stress Relief.
Implication of the Log-time Aging Law.
Aging with Two Simultaneous Log-time Mechanisms.
Figure 7 - Schematic Plot of Isothermal Aging at two Temperatures
Thermal Step Stress (Differential Thermal Analysis).
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The aging of quartz crystal resonators, filters and oscillators is reviewed, including the topics of: the impacts of aging, typical aging characteristics, aging specifications, aging mechanisms, temperature dependence of aging, frequency and overtone dependence of aging, drive level dependence of aging, the effects of aging interruptions, the dependence of aging on material and mode type, the state-of-the-art in low-aging oscillators, and aging acceleration effects. The aging mechanisms discussed include: contamination transfer effects, stress effects, electrode effects, diffusion effects, changes in the quartz material, and circuit and other electrical changes. Isothermal and thermal step stress aging acceleration methods are also reviewed.