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Abstract

This study demonstrates the realization of localized in-plane optomechanical microcavities embedded within an electrostatic MEMS architecture. The system consists of a curved, clamped-clamped microbeam, fabricated on a silicon-on-insulator (SOI) wafer. A green laser emitted from a Laser Doppler Vibrometer (LDV), is directed perpendicularly onto the device under a vacuum pressure of 7 mTorr, with the beam aligned to fill the gap between the movable microbeam and its adjacent side fixed mirror. This configuration forms localized cavity optomechanical resonators that enable the generation of optomechanical soliton frequency combs through phonon lasing without electrical excitation. The optomechanical resonators' dynamics are examined through experiments and numerical simulations. First, the experimental findings unveil that in electrostatic MEMS structures, the two reflective electrodes positioned to form a capacitive gap can inadvertently form localized cavities. These cavities significantly affect optical readouts, as the photodetected signal encodes contributions from both Doppler-shifted electromagnetic waves and light scattered from the intracavity optical field. This dual contributions can distort mechanical response interpretation unless appropriately filtered. Second, experiments show that optical pumping at various positions along the microbeam induces periodic pulse trains with distinct free spectral ranges (FSRs), each corresponding to different mechanical modes. Our results present the generation of solitary optical wavepackets using in-plane localized Fabry-P\'erot microcavities formed within a MEMS device. The results suggest a path toward chip-scale, soliton frequency combs generators featuring frequency spacing on the order of kilohertz, without relying on integrated fiber optics.