Cutting corners to suppress high-order modes in Mie resonator arrays

TL;DR

This study investigates how nanostructure shape in Mie resonator arrays influences color response and resonance suppression, providing design principles for polarization-sensitive metasurfaces with tunable colorimetric properties.

Contribution

It introduces a numerical framework linking nanostructure shape to colorimetric response and resonance behavior, offering new design guidelines for lattice resonant metasurfaces.

Findings

Shape transformation tunes colorimetric bounds.

Corner removal dampens high-order resonances.

Color saturation increases with T-shaped structures.

Abstract

Mie resonators as lattice resonant metasurfaces have the capability to produce structural colour. However, design criteria for these metasurfaces are still being investigated. In this work, we numerically examine how the two-dimensional nanostructure shape in a lattice array affects the colorimetric response of the metasurface under linearly polarised light excitation. First, the transformation from a square-shaped to rectangle-shaped nanostructure array resulted in polarisation-sensitive metasurfaces with colorimetric outputs bound along a line on the CIE 1931 2-degree Standard Observer colour space. The bounds of the colorimetry line were tuneable to any desired chromatic range. Second, the removal of the corners in square- or rectangle-shaped nanostructures to create t-shaped nanostructure arrays displayed a dampening effect on the high-order resonance. Finally, we analytically determined that the colour saturation could increase when moving from rectangle-shaped to t-shaped nanostructure arrays. From these results, we present two design guidelines for lattice resonant metasurfaces: (1) Constructing the nanostructure to support fundamental resonances at different wavelengths enables two-colour-bound movement when excited by successive angles of linearly polarised light; (2) Removing portions of the nanostructure that only support high-order resonances dampens these modes while maintaining support for fundamental resonances. These results present first-principles guidelines for engineering nanoparticles in lattice resonant metasurfaces, offering a new toolbox for polarised-light sensing and colorimetric applications.