Electromagnetic Metasurfaces - Christophe Caloz

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alpha Over 2 EndFraction"/> is a coupling parameter associated to chirality [26, 155] and where the parameter mu equals mu 0 slash left-parenthesis 1 minus omega squared mu 0 gamma right-parenthesis corresponds to artificial magnetism [122]. The constitutive relations (2.37) reveal, via (2.29), that chirality is related to spatial dispersion of the first order via alpha in nu, while artificial magnetism is related to spatial dispersion of the second order via gamma. Both chirality and artificial magnetism depend on the excitation frequency via omega. It may seem surprising that artificial magnetism is related to spatial dispersion but consider the following simple example, which is one of the easiest ways of creating an effective magnetic dipole. Consider, two small metal strips, one placed at a subwavelength distance d to the other in the direction of wave propagation. If the conditions are met, a mode with an odd current distribution may be excited on the strips resulting in an effective magnetic dipole. In that case, the electric field on one of the strip slightly differs from the one on the other strip since they are separated by a distance d, thus implying that the effective magnetic response of the strips spatially depends on the exciting electric field. If d right-arrow 0, then the difference of the electric field on the strips would vanish as would the effective magnetic dipole moment.

      It is not possible to further transform (2.37a) to eliminate the double spatial derivative associated with beta. However, it turns out that beta is most often negligible compared to nu and gamma, as discussed in [29, 148], so that this term may generally be ignored. Solving then (2.37) for bold upper B ultimately leads to the spatial-dispersion relations

      (2.38a)StartLayout 1st Row 1st Column bold upper D 2nd Column equals epsilon prime bold upper E plus xi bold upper H comma EndLayout

      (2.38b)StartLayout 1st Row 1st Column bold upper B 2nd Column equals zeta bold upper E plus mu bold upper H comma EndLayout

      Note that when omega right-arrow 0, then mu right-arrow mu 0 and epsilon prime right-arrow epsilon not-equals epsilon 0. This means that the permittivity and permeability have fundamentally different dispersive nature, a fact that has important consequences for metamaterials, as we will see throughout the book.

      Reciprocity or nonreciprocity is a fundamental physical property of all media, structures, devices, and systems. “A nonreciprocal (reciprocal) system is defined as a system that exhibits different (same) received–transmitted field ratios when its source(s) and detector(s) are exchanged” [28].

      A linear-time-invariant (LTI) system can be made nonreciprocal only via the application of an external bias field that is odd under time reversal, such as a magnetic field or a current. The most common example of a nonreciprocal device is the Faraday isolator, whose nonreciprocity is obtained by biasing a ferrite with an external static magnetic field [143].

      This section derives the Lorentz reciprocity theorem for a bianisotropic LTI medium, which provides the general conditions for reciprocity in terms of susceptibility tensors. These relations naturally apply to LTI metasurfaces as well.

      Similarly, the phase-conjugated impressed sources,5 bold upper J Superscript asterisk and bold upper K Superscript asterisk, are related to the phase-conjugated fields bold upper E Superscript asterisk, bold upper D Superscript asterisk, bold upper H Superscript asterisk, and bold upper B Superscript asterisk as