Piezoelectric MEMS Phase Modulator for Silicon Nitride Platform in the Visible Spectrum

Abstract

Active photonic integrated circuits (PICs) in the visible spectrum are essential for on-chip applications, requiring low-loss waveguides with broad transparency and efficient, low-power phase modulation. Here, we demonstrate a compact, ultra-low-power phase modulator based on a silicon nitride (Si3N4) waveguide integrated with thin-film lead zirconate titanate (PZT) that actuates a bridge-type MEMS. The suspended actuator exploits PZT's strong piezoelectric effect to induce mechanically driven phase shifts, enabling efficient modulation in a Mach--Zehnder interferometer. For 3~mm and 5~mm modulators, phase shifts of 1.45π and 2.5π are achieved at 10~V, corresponding to a scalability metric (Vπ· L) of 2.25~V·cm at 635~nm. This represents an order-of-magnitude improvement in scalability over stress-optic PZT modulators. The devices also exhibit ultralow power consumption ( 12\,nW), 5\,ms rise time, and optical loss < 0.75\,dB/cm. Furthermore, we demonstrate on-chip beam shaping.