Integrated plasmo-photonic sensor with voltage controled detection

TL;DR

This paper introduces a voltage-controlled plasmo-photonic interferometric sensor that detects ion distribution changes in liquids with high sensitivity, utilizing a waveguide-integrated Mach-Zehnder design for chemical and biological sensing.

Contribution

It presents a novel integrated plasmo-photonic sensor with voltage-controlled ion separation, enabling highly sensitive detection of liquid composition changes at telecom wavelengths.

Findings

Sensitivity over 12460 nm/RIU at 1550 nm

Voltage application enables ion drift and distribution control

Potential for enhanced sensitivity in mid-infrared wavelengths

Abstract

In this paper, we propose and analyze a waveguide-integrated interferometric sensor in which interference occurs between two plasmonic modes propagating in a single plasmonic waveguide. For the purpose of sensing, the vertical plasmonic slot waveguide was rearranged by increasing the distance between the metal electrodes. Consequently, the plasmonic modes associated with each metal electrode have been separated, enabling them to propagate independently on opposing edges of metal electrodes what allows for the implementation of a Mach-Zehnder interferometer. The metal electrodes that support the plasmonic modes can also function as electrical contacts. By applying a DC voltage between them, it is possible to efficiently separate ions that drift to one of the metal electrodes. Consequently, any change in a transmission from the interferometer refers only to the amount of ions in a liquid as the output signal from the interferometer is normalized to a liquid by the reference arm which is in direct contact with the examined liquid solution. The total amount of ions in the examined liquid remains constant, however, what changes is their distribution in the gap as the ions drift toward one of the metal electrodes when a voltage is applied. The proposed configuration is highly sensitive to variations in transmission between the two arms of the interferometer, enabling a record sensitivity of over 12460 nm/RIU, even at the telecom wavelength of 1550 nm. A further enhancement in sensitivity is expected in the mid-infrared wavelengths, which correspond to the maximum absorption peaks of most chemical and biological compounds.