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The Behavior of Gold Metallized AlN/Si- and AlN/Glass-Based SAW Structures as Temperature Sensors

Alexandra Nicoloiu, George E. Stan, Claudia Nastase, George Boldeiu, Cristina Beşleagă, Adrian Dinescu, A. Müller

2020IEEE Transactions on Ultrasonics Ferroelectrics and Frequency Control30 citationsDOI

Abstract

Thin AlN piezoelectric layers have been deposited on high resistivity Si and glass substrates by reactive RF magnetron sputtering, in order to manufacture one-port gigahertz operating surface acoustic wave (SAW)-type resonators to be used as temperature sensors. The growth morphology surface topography, crystallographic structure, and crystalline quality of the AlN layers have been analyzed. Advanced nanolithographic techniques have been used to manufacture structures having interdigitated transducers with fingers and finger interdigit spacing width in the range of 250-170 nm. High resonance frequency ensures the increase of the sensitivity, but also of its normalized value, the temperature coefficient of frequency (TCF). The resonance frequency shift versus temperature has been measured in the -267°C-+150°C temperature range, using a cryostat setup adapted for on wafer microwave measurements up to 50 GHz. The sensitivity and the TCF were determined in the 25 °C-150 °C temperature range.

Topics & Concepts

Materials scienceWaferTemperature coefficientResonatorOptoelectronicsSputter depositionSurface acoustic waveMicrowaveSputteringAtmospheric temperature rangeResonance (particle physics)PiezoelectricityCryostatCavity magnetronThin filmOpticsComposite materialNanotechnologySuperconductivityMeteorologyParticle physicsPhysicsQuantum mechanicsAcoustic Wave Resonator TechnologiesGaN-based semiconductor devices and materialsMetal and Thin Film Mechanics
The Behavior of Gold Metallized AlN/Si- and AlN/Glass-Based SAW Structures as Temperature Sensors | Litcius