Title :
Nanostructured Metal Oxide Thin Films for Humidity Sensors
Author :
Steele, John J. ; Taschuk, Michael T. ; Brett, Michael J.
Author_Institution :
Dept. of Electr. & Comput. Eng., Alberta Univ., Edmonton, AB
Abstract :
Capacitive humidity sensors were fabricated using countersunk interdigitated electrodes coated with amorphous nanostructured TiO2, SiO2, and Al2O3 thin films grown by glancing angle deposition. The capacitive response and response times for each sensor were measured. The sensor utilizing TiO2 exhibited the largest change in capacitance, increasing exponentially from ~ 1 nF to ~ 1muF for an increase in relative humidity from 2% to 92%. Adsorption and desorption response times were measured using flow rates of 2.5 l/min and were between 90 ms and 300 ms for the sensors studied here. A simple model of the capacitive response of the devices has been developed and used to calculate the dielectric constant of the combined system of our films and adsorbed water. The obtained dielectric constants are found to be much higher than bulk or literature values for similar systems.
Keywords :
adsorption; aluminium compounds; capacitive sensors; coating techniques; desorption; humidity sensors; nanostructured materials; permittivity; silicon compounds; thin films; titanium compounds; Al2O3; SiO2; TiO2; adsorption response times; amorphous nanostructured thin films; capacitive humidity sensors; countersunk interdigitated electrodes; desorption response times; dielectric constant; flow rates; glancing angle deposition; nanostructured metal oxide thin films; relative humidity; Amorphous materials; Capacitance; Capacitive sensors; Delay; Dielectric constant; Dielectric measurements; Electrodes; Humidity; Sputtering; Thin film sensors; Glancing angle deposition (GLAD); humidity; metal oxide; model development; nanostructured; porous; sensor; thin film;
Journal_Title :
Sensors Journal, IEEE
DOI :
10.1109/JSEN.2008.920715
