Abstract
We investigate magnetoinductive waves in two-dimensional periodic arrays of split ring resonators or capacitively loaded loops and characterize the modes with real and complex wavenumber excitable in such arrays. Each resonator is modeled as a single magnetic dipole, and the computation of the modal wavenumbers is performed by searching for the zeroes of the homogeneous scalar equation characterizing the field in the array. We provide original developments for the Ewald method applied to the required dyadic periodic Green's function for the array of magnetic dipoles, including the quasi-static case. The Ewald representation is analytically continued into the complex wavenumber space and also provides series with Gaussian convergence rate. In particular, we analyze and classify proper, improper, forward, backward, bound, and leaky magnetoinductive waves varying frequency and compare the fully retarded solution to the quasi-static one. We highlight the importance of accounting for field retardation effects for the prediction of the physical waves excitable in the array when the dimensions of its unit cell are approximately greater than a tenth of the free-space wavelength. The proposed method complements previous investigations and is a powerful tool for the design of waveguiding or radiating structures based on magnetoinductive waves.
Highlights
M AGNETICALLY coupled resonators can support propagating waves, which are generally referred to as magnetoinductive (MI) waves
When the gap is aligned along, both reflection and transmission exhibit a slightly wider resonance behavior compared with those from the single dipole approximation (SDA), due to the split ring resonators (SRRs) coupling with the electric field
We show curves computed by using the Green’s function (GF) with field retardation (FR) effects (7)
Summary
M AGNETICALLY coupled resonators can support propagating waves, which are generally referred to as magnetoinductive (MI) waves. These resonators may be for example used to achieve left-handed metamaterials [1], effective negative permeability [2], and tunable metamaterial components [3]. The dispersion properties of a bi-periodic linear array of SRRs (contiguous loops are loaded with different capacitances) have been shown experimentally in [16] to support MI waves in two distinct frequency bands. CAMPIONE et al.: MAGNETOINDUCTIVE WAVES AND COMPLEX MODES IN 2D PERIODIC ARRAYS OF SPLIT RING RESONATORS to tailor the dispersion diagrams has been shown in [18]. This paper presents a number of novel discussions and numerical results
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