Plasmonic Spin Meron Lattices with Height-Sensitive Topology Evolution

TL;DR

This paper demonstrates how height adjustments in plasmonic spin meron lattices can induce topological phase transitions, with potential applications in tunable nanophotonic devices.

Contribution

It introduces a method for height-controlled topological switching in plasmonic lattices, combining analytical models and simulations to reveal rich topological evolutions.

Findings

Height-dependent topological phase switching observed.

Nucleation of vortex-anti vortex pairs at intermediate heights.

Analytical and numerical models confirm the topological transitions.

Abstract

We demonstrate height-controlled topological switching of plasmonic spin meron lattices above a metallic square coupling structure under circularly polarized illumination. Near the interface, an evanescent surface plasmon polariton (SPP) channel yields a N\'eel-type meron lattice with $\pm\frac{1}{2}$ like effective site charges. At larger heights, diffracted fields from the square edges dominate and convert the lattice into a Bloch-type configuration. Over a range of intermediate heights, crossover between the evanescent SPP and edge diffraction gives rise to rich rapid topology evolutions. The switching is accompanied by nucleation of off-boundary vortex-anti vortex pairs in the in-plane spin phase, producing height-dependent fractional site charges. Our findings are analytically formulated by linear superposition of SPPs in the plasmonic regime and Stratton-Chu model in diffraction regime and confirmed via full-wave finite-difference time-domain simulations.