Design and Simulation of Si-Photonic Nanowire-Waveguides with DEP Concentration Electrodes for Biosensing Applications

TL;DR

This paper explores the design and simulation of silicon nanowire waveguides with integrated dielectrophoresis electrodes to enhance biosensing capabilities, focusing on electrode configurations for improved analyte manipulation.

Contribution

It introduces a novel electrode configuration for nanowire waveguides using PIC technology, supported by FEM simulations to optimize biosensing performance.

Findings

Planar electrode geometry on device layer is most effective.

Second electrode pair on metal 1 layer enhances DEP efficiency.

Simulation results guide practical electrode design for biosensors.

Abstract

Silicon-based photonic biosensors, such as microring resonators and Mach-Zehnder interferometers, offer significant potential for the detection of analytes at low concentrations. To enhance response time and improve the limit of detection within practical time scales, dielectrophoresis (DEP) has been proposed as a viable solution. In this approach, two electrodes are placed in close proximity to the sensor surface. By applying an AC field, analytes are transported to the sensor surface due to the polarization of the solvent and the particles, effectively overcoming the diffusion barrier. In this communication, we explore various possibilities for realizing DEP electrodes for nanowire waveguides using commercially available photonic integrated circuit (PIC) technology. Finite Element Method (FEM) simulations suggest that the most beneficial electrode configuration is a planar electrode geometry on the device layer combined with a second electrode pair on the metal 1 layer.