Reconfigurable plasmonic hot spots enabled by composite VO2-gold plasmonic antennas

TL;DR

This paper explores reconfigurable plasmonic antennas using composite VO2-gold materials, enabling switching between electric and magnetic hot spots with enhanced optical properties.

Contribution

It introduces a composite VO2-gold platform that allows switching between electric and magnetic hot spots within a single antenna, advancing reconfigurable plasmonic device design.

Findings

Composite VO2-gold antennas can switch hot spot types.

Enhanced optical absorption in composite systems.

Demonstration of joint electric-magnetic hotspots.

Abstract

We theoretically investigate the formation of electric and magnetic hot spots with reconfigurable plasmonic antennas. We consider three material systems offering different levels of reconfigurability: gold with the static response, vanadium dioxide which allows for ON/OFF switching, and composite gold-vanadium dioxide material platform which offers a possibility to switch between the electric and magnetic hot spot within a single antenna. Using bowtie and diabolo antennas as a case study, we evaluate optical response functions (scattering and absorption cross-sections, electric and magnetic field enhancement). We demonstrate that the composite material system brings, in addition to enhanced reconfigurability, also novel features of plasmonic antennas, such as strong optical absorption and a joint electric-magnetic hotspot.