Electromagnetic Metasurfaces. Christophe Caloz

Electromagnetic Metasurfaces - Christophe Caloz


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polarization densities in (2.1) are typically expressed in terms of quantities which are either microscopic, the polarizabilities, or macroscopic, the susceptibilities. Although both the microscopic and macroscopic descriptions are applicable for modeling metasurfaces, we will mostly use the macroscopic model throughout the book, because it more conveniently describes metasurfaces as homogeneous media. For a bianisotropic metasurface, the polarization densities in (2.1) read

      (2.2b)StartLayout 1st Row 1st Column bold upper M 2nd Column equals chi overbar overbar Subscript mm Baseline dot bold upper H plus StartFraction 1 Over eta 0 EndFraction chi overbar overbar Subscript me Baseline dot bold upper E comma EndLayout

      (2.3b)StartLayout 1st Row 1st Column bold upper B 2nd Column equals mu 0 left-parenthesis upper I overbar overbar plus chi overbar overbar Subscript mm Baseline right-parenthesis dot bold upper H plus StartFraction 1 Over c 0 EndFraction chi overbar overbar Subscript me Baseline dot bold upper E comma EndLayout

      where upper I overbar overbar is the unity dyadic tensor. Sometimes, these relations are also expressed in the more compact form

      (2.4b)StartLayout 1st Row 1st Column bold upper B 2nd Column equals zeta overbar overbar dot bold upper E plus mu overbar overbar dot bold upper H comma EndLayout

      where epsilon overbar overbar (F/m), mu overbar overbar (H/m), xi overbar overbar (s/m), and zeta overbar overbar (s/m) are the permittivity, permeability, magnetic-to-electric, and electric-to-magnetic tensors, respectively.

      Practically, some of the 16 media types represented in Figure 2.1 are still challenging. For instance, time-varying (ModifyingAbove Above ModifyingAbove chi With bar With bar left-parenthesis t right-parenthesis) or spatially dispersive (ModifyingAbove Above ModifyingAbove chi With bar With bar left-parenthesis bold k right-parenthesis) metamaterials are more difficult to realize than spatially varying ones (ModifyingAbove Above ModifyingAbove chi With bar With bar left-parenthesis bold r right-parenthesis), which only involve a spatial modulation in their geometry. Moreover, all the materials are de facto temporally dispersive,2 and particularly metamaterials, which strongly rely on resonant scattering particles to manipulate electromagnetic waves. Finally, some of these dependency combinations are also restricted by the uncertainty principle, as shown in [24]. Thus, metamaterial technology is often limited to a subset of the material types in Figure 2.1. Specifically, the most common types of metamaterials exhibit material parameters such as ModifyingAbove Above ModifyingAbove chi With bar With bar left-parenthesis omega right-parenthesis (e.g. quarter/half-wave plates) and ModifyingAbove Above ModifyingAbove chi With bar With bar left-parenthesis <hr><noindex><a href=Скачать книгу