Monolithic piezo-magnonic-MEMS for efficient modulation of RF signals
Abstract
Compact, low-power analog RF components are essential for next-generation microwave electronics and wireless systems. We demonstrate an all-electric integrated piezo-magnonic microelectromechanical system that enables efficient voltage control of GHz spin-wave signals via magnetoelastic coupling. Exploiting the large strain in a CoFeB magnonic waveguide integrated on a silicon bridge with piezoelectric actuation, very large values of the magnetoelectric field (up to 30\,mT at 30\,V) are obtained, thus achieving reversible phase and amplitude control of propagating spin waves. In the static regime, we achieve either up to 4π phase modulation or ≈ 50\,dB amplitude attenuation with drive voltages below 20\,V at 7\,GHz. Leveraging the bridge's first bending resonance (≈ 17\,kHz) yields resonant enhancement of the phase modulation efficiency. This allows us to achieve a 2π phase swing with just 2.2\,V drive and power consumption of ≈ 6\,μW. Our results highlight piezo-magnonic MEMS as a promising new class of devices for reconfigurable RF front ends and analog signal processors.
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