Achieving Optical Refractive Index of 10-Plus by Colloidal Self-Assembly
arxiv(2024)
摘要
This study demonstrates the developments of self-assembled optical
metasurfaces to overcome inherent limitations in polarization density (P)
within natural materials, which hinder achieving high refractive indices (n) at
optical frequencies. The Maxwellian macroscopic description establishes a link
between P and n, revealing a static limit in natural materials, restricting n
to approximately 4.0 at optical frequencies. Optical metasurfaces, utilizing
metallic colloids on a deep-subwavelength scale, offer a solution by
unnaturally enhancing n through electric dipolar (ED) resonances. Self-assembly
enables the creation of nanometer-scale metallic gaps between metallic
nanoparticles (NPs), paving the way for achieving exceptionally high n at
optical frequencies. This study focuses on assembling polyhedral 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
study underlies the significance of capacitive coupling in achieving an
unnaturally high n and explores fine-tuning Au NC size to optimize this
coupling. The achieved n of 10.12 at optical frequencies stands as a benchmark,
highlighting the potential of polyhedral Au NPs in advancing optical
metasurfaces.
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