Millivolt modulation of plasmonic metasurface via ionic conductance

TL;DR

This paper demonstrates a voltage-controlled plasmonic metasurface with low-voltage operation (<1V) using ionic conductance, enabling significant modulation of reflectance in the visible spectrum.

Contribution

It introduces a novel actively tunable metasurface based on ion conductance, achieving large reflectance changes with very low voltages, which is a significant advancement in active plasmonic devices.

Findings

Up to 78% reflectance change with <1V voltage

Active resistive switching via ion conductance in silver

Broadband decrease in reflection upon bias reversal

Abstract

We report here and experimentally demonstrate an actively controlled gatetunable plasmonic metasurface operating in the visible region of the electromagnetic spectrum, where strikingly the operating voltages for reflectance modulation are much less than 1V. The electrically tunable metasurface consists of inverse dolmen structures (iDolmen) patterned on silver and chromium on a quartz substrate and subsequently covered with a 5 nm thin layer of Al2O3 followed by a 110 nm indium tin oxide (ITO) layer, which acts as a transparent electrode. Our designed structures show up to 78 percent change in reflection upon applying small voltages (less than 1V). We explain this behaviour via ion conductance of silver through Al2O3 and ITO, leading to active resistive switching. Interesting complementary effects such as decreased reflection in the same structures over a broadband of wavelengths is also seen on reversing the applied bias. The results provide an insight into the use of the resistive switching for electrical control over light-matter interaction in plasmonic metasurfaces.