Litcius/Paper detail

Ultra-High-Q Gallium Nitride SAW Resonators for Applications With Extreme Temperature Swings

Afzaal Qamar, Savannah R. Eisner, Debbie G. Senesky, Mina Rais‐Zadeh

2020Journal of Microelectromechanical Systems28 citationsDOI

Abstract

In this paper, we present ultra-high quality factor (${Q}$ ) SAW resonators fabricated on aluminum gallium nitride on gallium nitride on silicon (AlGaN/GaN/Si) heterostructures with ${Q}$ exceeding 6000 at room temperature. We characterize their temperature response in a broad range of temperature (-196°C to 500°C or 77 K to 773 K). The effect of doping on the ${Q}$ and temperature coefficient of frequency (TCF) of the GaN-based SAW resonators is analyzed, for the first time, using un-intentionally doped GaN (UID-GaN), carbon doped GaN (C-doped), and Si doped GaN. The ${Q}$ value for UID-GaN and C-doped GaN is similar and decreases from 2000 to 1000 as the temperature is increased from 77 K to 773 K. The ${Q}$ value of Si-doped GaN is higher than UID and C-doped GaN by a factor of 3 (6622 at 77 K) and decreases with increase of temperature. This value of ${Q}$ at 1.8 GHz is the highest reported amongst aluminum nitride (AlN) or GaN-based SAW resonators. For extreme high temperatures (≥573 K) the TCF value is half the TCF value of UID and C-doped GaN, which shows the possibility of engineering the TCF by tuning the doping concentration. For low temperatures (≤150 K) C-doped and UID-GaN show a turn over point in TCF curve which shows their promise for cold clocks. [2020-0163]

Topics & Concepts

Gallium nitrideMaterials scienceDopingNitrideGalliumOptoelectronicsResonatorAtmospheric temperature rangeWide-bandgap semiconductorSilicon nitrideSiliconAnalytical Chemistry (journal)NanotechnologyPhysicsChemistryMetallurgyLayer (electronics)ThermodynamicsChromatographyGaN-based semiconductor devices and materialsAcoustic Wave Resonator TechnologiesSemiconductor Quantum Structures and Devices