Single-step fabrication of high performance extraordinary transmission plasmonic metasurfaces employing ultrafast lasers

TL;DR

This paper introduces a rapid, single-step ultrafast laser fabrication method for high-performance plasmonic EOT metasurfaces, enabling efficient transmission control across spectral regimes with minimal processing steps.

Contribution

The work presents a novel ultrafast laser direct writing technique for fabricating EOT metasurfaces in a single step, reducing complexity and cost compared to traditional lithography.

Findings

Micro-hole arrays fabricated in minutes over 4 mm² areas.

Optical properties can be tuned via laser parameters.

Fabricated devices match numerical simulations.

Abstract

Plasmonic metasurfaces based on the extraordinary optical transmission effect (EOT) can be designed to efficiently transmit specific spectral bands from the visible to the far-infrared regimes, offering numerous applications in im-portant technological fields such as compact multispectral imaging, biological and chemical sensing, or color displays. However, due to their subwavelength nature, EOT metasurfaces are nowadays fabricated with nano- and micro-lithographic techniques, requiring many processing steps and carried out in expensive cleanroom environments. In this work, we propose and experimentally demonstrate a novel, single-step process for the rapid fabrication of high performance mid- and long-wave infrared EOT metasurfaces employing ultrafast direct laser writing (DLW). Micro-hole arrays composing extraordinary transmission metasurfaces were fabricated over areas of 4 mm2 in timescales of units of minutes, employing single pulse ablation of 40 nm thick Au films on dielectric substrates mounted on a high-precision motorized stage. We show how by carefully characterizing the influence of only three key experimental pa-rameters on the processed micro-morphologies (namely laser pulse energy, scan velocity and beam shaping slit), we can have on-demand control of the optical characteristics of the extraordinary transmission effect in terms of transmission wavelength, quality factor and polarization sensitivity of the resonances. To illustrate this concept, a set of EOT metasurfaces having different performances and operating in different spectral regimes has been successfully designed, fabricated and tested. Comparison between transmittance measurements and numerical simulations have revealed that all the fabricated devices behave as expected, thus demonstrating the high performance, flexibility and reliability of the proposed fabrication method.