Abstract
Self-assembled metamaterials attract considerable interest as they promise to make isotropic bulk metamaterials available at low costs. The optical response of self-assembled metamaterials is derived predominantly from the response of its individual constituents, i.e., the meta-atoms. Beyond effective properties, primary experimentally observable quantities, such as specific cross-sections, are at the focus of interest as they are frequently considered when exploiting metamaterials in specific applications. This posses the challenge of predicting these observable quantities for a diluted ensemble of randomly oriented meta-atoms. Thus far, this has been achieved by either averaging the optical response of the meta-atom across all possible incident fields or by restricting the consideration to only an electric and magnetic dipolar response. This, however, is either time-consuming or imposes an unnecessary limitation. Here, we solve this problem by deriving and presenting explicit expressions for experimentally observable quantities of metamaterials made from randomly arranged and oriented meta-atoms characterized by their T-matrix.
Highlights
IntroductionMetamaterials are artificial materials that exhibit unique properties not encountered in nature
Metamaterials are artificial materials that exhibit unique properties not encountered in nature.The properties of metamaterials are largely derived from the scattering properties of its constituents, the so called meta-atoms
The recent advances in the field of metamaterials has opened up many unprecedented means of light manipulation [1,2,3,4,5,6]
Summary
Metamaterials are artificial materials that exhibit unique properties not encountered in nature. For an arbitrarily shaped meta-atom, the response has been deduced far by averaging the response of the individual meta-atom across all possible orientations of the meta-atom relative to the illumination [38,39] This can be an extremely tedious task, as quite some quantities of interest show a very poor convergence with respect to the considered number of illuminations, as we will show later in the article. To solve this problem, we develop here a methodological framework that allows to predict experimentally observable quantities of sufficiently diluted self-assembled metamaterials directly from the T-matrix of their constituent. We concentrate on the example of a helical arrangement of metallic nanoparticles; being an ensemble that unifies the beauty of possessing a dispersive response in all the quantities we are interested in and being of practical relevance
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