Nonvolatile Silicon Photonic MEMS Switch Based on Centrally-Clamped Stepped Bistable Mechanical Beams

TL;DR

This paper introduces a nonvolatile silicon photonic MEMS switch with bistable mechanical beams, enabling low-power, fast switching suitable for large-scale optical routing and programmable photonic circuits.

Contribution

It presents a novel nonvolatile 2*2 silicon photonic switch using centrally-clamped stepped bistable beams compatible with standard fabrication processes.

Findings

Switching speed of tens of microseconds

Switching energy in the tens of femtojoules

Compact footprint of 100x100 micrometers

Abstract

High-performance photonic switches are essential for large-scale optical routing for AI large models and Internet of things. Realizing nonvolatility can further reduce power consumption and expand application scenarios. We propose a nonvolatile 2*2 silicon photonic micro-electromechanical system (MEMS) switch compatible with standard silicon photonic foundry processes. The switch employs electrostatic comb actuator to change the air gap of the compact horizontal adiabatic coupler and achieves nonvolatility with centrally-clamped stepped bistable mechanical beams. The photonic switch features a 10s us-scale switching speed and a 10s fJ-scale simulated switching energy within a 100*100 um2 footprint, with <=12 V driving voltages. This 2*2 switch can be used in a variety of topologies for large-scale photonic switches, and its nonvolatility can potentially support future photonic FPGA designs.