A plasmonic painter's method of color mixing for a continuous RGB palette

TL;DR

This paper introduces a novel plasmonic metasurface approach for nanophotonic color mixing, enabling smooth, continuous RGB color gradients and photorealistic nanoscale printing with potential applications in displays and filters.

Contribution

It presents a single-layer plasmonic color pixel design that allows independent control of color brightness and enables multi-color mixing for a broad RGB gamut.

Findings

Demonstrated continuous RGB color coverage with plasmonic nanorod arrays.

Achieved ultra-smooth color and brightness transitions in nanoscale printing.

Enabled multi-wavelength color filters and dynamic photorealistic displays.

Abstract

The ability of mixing colors with remarkable results had long been exclusive to the talents of master painters. By finely combining colors at different amounts on the palette intuitively, they obtain smooth gradients with any given color. Creating such smooth color variations through scattering by the structural patterning of a surface, as opposed to color pigments, has long remained a challenge. Here, we borrow from the painter's approach and demonstrate color mixing generated by an optical metasurface. We propose a single-layer plasmonic color pixel and a method for nanophotonic structural color mixing based on the additive RGB color model. The color pixels consist of plasmonic nanorod arrays that generate vivid primary colors and enable independent control of color brightness without affecting chromaticity, by simply varying geometric in-plane parameters. By interleaving different nanorod arrays, we combine up to three primary colors on a single pixel. Based on this, two and three color mixing is demonstrated, enabling the continuous coverage of a plasmonic RGB color gamut and yielding a palette with a virtually unlimited number of colors. With this multi-resonant color pixel, we show the photorealistic printing of color and monochrome images at the nanoscale, with ultra-smooth transitions in color and brightness. Our color mixing approach can be applied to a broad range of scatterer designs and materials, and has the potential to be used for multi-wavelength color filters and dynamic photorealistic displays.