
Hyperbolic Optical Metamaterials from Shear‐Aligned Block Copolymer Cylinder Arrays
Author(s) -
Kilchoer Cédric,
Abdelrahman Doha,
Abdollahi S. Narjes,
LaRocca Ava A.,
Steiner Ullrich,
Saba Matthias,
Gunkel Ilja,
Wilts Bodo D.
Publication year - 2020
Publication title -
advanced photonics research
Language(s) - English
Resource type - Journals
ISSN - 2699-9293
DOI - 10.1002/adpr.202000037
Subject(s) - materials science , metamaterial , nanostructure , polarizer , optics , anisotropy , cylinder , optoelectronics , nanophotonics , polarization (electrochemistry) , nanotechnology , birefringence , physics , geometry , chemistry , mathematics
Hyperbolic metamaterials behave similarly to either metals or dielectrics depending on the polarization of incident light. This behavior is reflected in permittivity tensors having both negative and positive components, which leads to interesting optics such as negative refraction and super‐resolution imaging. To achieve this polarization‐dependent electromagnetic response, hyperbolic metamaterials require a strongly anisotropic nanostructure made from noble metals. Herein, a nanostructured array of aligned gold and silver nanocylinders that exhibit a strongly anisotropic optical response both in reflection and transmission are investigated. The plasmonic material is manufactured using films of aligned block copolymer (BCP) cylinders as template, where a uniform alignment is achieved by annealing in the presence of an external shear force. Metal deposition into a nanoporous polymer template resulted in free‐standing metal nanostructures consisting of a hexagonally packed in‐plane cylinder array supported by occasional interconnections between adjacent cylinders. 3D full‐wave simulations confirm the experimentally measured anisotropic response of the metallic nanocylinders and show that the interconnections between cylinders affect the optical response while maintaining the hyperbolic nature of the metamaterial. The large‐scale alignment of anisotropic BCP nanostructures provides useful templates for the fabrication of metal‐based optical materials with potential applications as polarizers, sensors, or angle‐dependent broadband absorbers.