Plasmonic Metal Oxide Nanocrystals as Building Blocks for Infrared Metasurfaces

TL;DR

This paper explores how self-assembled plasmonic metal oxide nanocrystals can be used to create advanced infrared metasurfaces with tunable optical properties, enhanced molecular detection, and potential for nonlinear optical applications.

Contribution

It introduces a mechanistic understanding of self-assembled nanocrystal metamaterials and demonstrates their integration into photonic structures for tailored infrared optical responses.

Findings

Self-assembly defects can be advantageous for optical properties.

Enhanced molecular vibration detection via field localization in NC gaps.

Designed a frequency-tunable IR perfect absorber using NC metasurfaces.

Abstract

Based on experimental and simulation methods we helped develop, we are advancing mechanistic understanding of how self-assembled NC metamaterials can produce distinctive near- and far-field optical properties not readily achievable in lithographically patterned structures. First, the impacts of the inevitable defects and disorder associated with self-assembly can be rationalized and, in some cases, recognized as advantageous. Second, self-assembly enables intimate nanoscale intermixing of different NC and molecular components. By incorporating probe molecules within the gaps between NCs where the electric field enhancement is strongest, we show enhanced detection of molecular vibrations that can be optimized by tuning the size and resonance frequency of the NCs. We show how metasurfaces incorporating mixtures of NCs with different doping concentrations can achieve epsilon-near-zero dielectric response over a broad frequency range. Finally, considering the NC metasurface itself as a building block, we show how photonic structures incorporating these assemblies can harness and amplify their distinctive properties. Through modeling the NC monolayer as a slab with an effective permittivity response, we designed a frequency-tunable IR perfect absorber by layering the NCs on a simple open cavity structure. Since the perfect absorption architecture further enhances the IR electric field localization strength, we expect that this integration strategy can enhance molecular vibration coupling or non-linear optical response. The versatility of the NC assembly and integration approach suggests opportunities for various metal oxide NC superstructures, including mixing and stacking of NCs beyond a single monolayer, representing a vast parameter space for design of linear and nonlinear IR optical components.