Affiliation:
1. KU‐KIST Graduate School of Converging Science and Technology Korea University Seoul 02841 Republic of Korea
2. Department of Applied Physics Hanyang University Ansan 15588 Republic of Korea
3. Department of Integrated Energy Engineering (College of Engineering) Department of Biomicrosystem Technology and KU Photonics Center Korea University Seoul 02841 Republic of Korea
4. Center for Opto‐Electronic Materials and Devices Post‐Silicon Semiconductor Institute Korea Institute of Science and Technology (KIST) Seoul 02792 Republic of Korea
Abstract
AbstractThis study demonstrates the developments of self‐assembled optical metasurfaces to overcome inherent limitations in polarization density (P) and high refractive indices (n) within naturally occurring materials. The Maxwellian macroscopic description establishes a link between P and n, revealing a static limit in natural materials, restricting n to ≈4.0 at optical frequencies. Previously, it is accepted that self‐assembly enables the creation of nanogaps between metallic nanoparticles (NPs), boosting capacitive enhancement of P and resultant exceptionally high n at optical frequencies. The work focuses on assembling gold (Au) NPs into a closely packed monolayer by rationally designing the polymeric ligand to balance attractive and repulsive forces, in that polymeric brush‐mediated self‐assembly of the close‐packed Au NP monolayer is robustly achieved over a large‐area. The resulting monolayer of Au nanospheres (NSs), nanooctahedras (NOs), and nanocubes (NCs) exhibits high macroscopic integrity and crystallinity, sufficiently enough for pushing n to record‐high regimes. The systematic comparisons between each differently shaped Au NP monolayers elucidate the significance of capacitive coupling in achieving an unnaturally high n. The achieved n of 10.12 at optical frequencies stands as a benchmark, highlighting the potential of polyhedral Au NPs in advancing optical metasurfaces.
Funder
National Research Foundation