Title :
Electrochemical detection of localized mixing produced by ultrasonic flexural waves
Author :
Tsao, T.R. ; Moroney, R.M. ; Martin, B.A. ; White, R.M.
Author_Institution :
California Univ., Berkeley, CA, USA
Abstract :
Localized fluid mixing caused by both standing and traveling flexural waves in 4 μm thick membranes of low-stress silicon nitride, aluminum, and piezoelectric zinc oxide has been observed. Initial work on quantifying the mixing action using a ferri-ferrocyanide electrochemical cell is presented. One electrode is fabricated directly on the membrane; the cell current, limited by diffusion, increases from the enhanced ion transport due to the mixing. For a cell bias of 0.5 V, an increase in the limiting current from 4.2 mA without mixing to 6.6 mA with standing waves driven by 10 V at 5.0 MHz was observed. This is roughly equivalent to a rotating disk electrode spinning at 140 rpm. Possible applications include increasing the speed of amperometric sensors and as components in integrated microflow systems
Keywords :
chemical sensors; electrochemical analysis; membranes; mixing; surface acoustic wave devices; ultrasonic applications; 4.2 to 6.6 mA; 5 MHz; Al; Si3N4; ZnO; amperometric sensors; cell current; electrochemical detection; enhanced ion transport; ferri-ferrocyanide electrochemical cell; flexural plate wave devices; integrated microflow systems; limiting current; localized fluid mixing; membranes; standing waves; traveling flexural waves; ultrasonic flexural waves; Chemicals; Counting circuits; Electrodes; Equations; Oxidation; Platinum; Polarization; Pollution measurement; Transducers; Voltage;
Conference_Titel :
Ultrasonics Symposium, 1991. Proceedings., IEEE 1991
Conference_Location :
Orlando, FL
DOI :
10.1109/ULTSYM.1991.234251
