Acoustic mode confinement using coupled cavity structures in UHF unreleased MEMS resonators

Abstract: This papers investigates device approaches towards the confinement of acoustic modes in unreleased UHF MEMS resonators. Acoustic mode confinement is achieved using specially designed mechanically coupled acoustic cavities known as acoustic Bragg Grating Coupler structures to spatially localize the vibration energy within the resonators and thereby improve the motional impedance (R x) and mechanical quality factor (Q). This enhancement in the mechanical response is demonstrated with numerical simulations using … Show more

“…In addition, by trapping these sound waves using guided mode resonances 10 , one a) Electronic mail: krishna.coimbatorebalram@bristol.ac.uk can engineer high quality factor (Q mech ) resonators without requiring substrate release. Such unreleased resonator platforms are also being explored for monolithic integration in nonpiezoelectric CMOS-MEMS platforms [11][12][13][14] . In this work, we demonstrate high Q mech GaN resonators on unreleased substrates (sapphire and silicon carbide) by utilizing the metallic interdigitated transducer (IDT) electrodes for mass loading and energy trapping 15 .…”

High frequency guided mode resonances in mass-loaded, thin film gallium nitride surface acoustic wave devices

“…In addition, by trapping these sound waves using guided mode resonances 10 , one a) Electronic mail: krishna.coimbatorebalram@bristol.ac.uk can engineer high quality factor (Q mech ) resonators without requiring substrate release. Such unreleased resonator platforms are also being explored for monolithic integration in nonpiezoelectric CMOS-MEMS platforms [11][12][13][14] . In this work, we demonstrate high Q mech GaN resonators on unreleased substrates (sapphire and silicon carbide) by utilizing the metallic interdigitated transducer (IDT) electrodes for mass loading and energy trapping 15 .…”

High frequency guided mode resonances in mass-loaded, thin film gallium nitride surface acoustic wave devices

Analytical modeling of mechanical behavior for MEMS/NEMS-based single-clamped multilayer resonators with symmetrical complex shapes

High-Q multi-frequency ring-shaped piezoelectric MEMS resonators