Design and modeling of an ultra-compact 2x2 nanomechanical plasmonic switch

TL;DR

This paper presents a compact 2x2 nanomechanical plasmonic switch with a tiny footprint, demonstrating low loss, high extinction ratio, and effective crosstalk suppression through finite-element modeling.

Contribution

It introduces a novel ultra-compact 2x2 plasmonic switch design utilizing nanomechanical gap phase modulators with detailed modeling and optimization.

Findings

Insertion loss ≤ 8.5 dB

Extinction ratio > 25 dB

Crosstalk > 24 dB

Abstract

A 2x2 Mach-Zehnder optical switch design with a footprint of 0.5 ${\mu}$m x 2.5 ${\mu}$m using nanomechanical gap plasmon phase modulators [arXiv:1410.0273] is presented. The extremely small footprint and modest optical loss are enabled by the strong phase modulation of gap plasmons in a mechanically actuated 17 nm air gap. Frequency-domain finite-element modeling at 780 nm shows that the insertion loss is ${\leq}$ 8.5 dB, the extinction ratio is > 25 dB, and crosstalk for all ports is > 24 dB. A design optimization approach and its dependence on geometrical parameters are discussed.