Dispersion relation, propagation length and mode conversion of surface plasmon polaritons in silver double-nanowire systems

TL;DR

This paper analyzes surface plasmon polariton modes in silver double-nanowire systems, revealing new mode behaviors and proposing methods for efficient excitation and mode conversion to enhance plasmonic circuit performance.

Contribution

It provides a detailed eigenmode analysis of plasmon modes in double-nanowire systems, identifying new mode characteristics and demonstrating excitation and conversion techniques.

Findings

Mode 2 has higher group velocity and longer propagation length than mode 1.

Three groups of modes originate from different hybridizations.

Efficient excitation and conversion scenarios for modes are demonstrated.

Abstract

We study the surface plasmon modes in a silver double-nanowire system by employing the eigenmode analysis approach based on the finite element method. Calculated dispersion relations, surface charge distributions, field patterns and propagation lengths of ten lowest energy plasmon modes in the system are presented. These ten modes are categorized into three groups because they are found to originate from the monopole-monopole, dipole-dipole and quadrupole-quadrupole hybridizations between the two wires, respectively. Interestingly, in addition to the well studied gap mode (mode 1), the other mode from group 1 which is a symmetrically coupled charge mode (mode 2) is found to have a larger group velocity and a longer propagation length than mode 1, suggesting mode 2 to be another potential signal transporter for plasmonic circuits. Scenarios to efficiently excite (inject) group 1 modes in the two-wire system and also to convert mode 2 (mode 1) to mode 1 (mode 2) are demonstrated by numerical simulations.