Abstract
In the present article, we have analyzed the dispersion of electromagnetic wave in the one dimensional magnetized ferrite photonic crystals near the resonance in the permeability of the constituent materials for transverse magnetization in the transverse electric mode. The dispersion relation is obtained by transfer matrix method. It is observed that in the vicinity of resonant frequency, large numbers of oscillations occur in the normalized Bloch wave number. These oscillations in the Bloch wave number are strongly dependent on external magnetic fields, filling factor, and damping constant. The frequency regime of these oscillations is found to be shifted in higher frequency range with increase in the magnitude of the magnetic fields. With increase in the filling factor keeping length of periods fixed, number of oscillations is found to be increased. Near the resonance, effect of incident angle is negligible. It is demonstrated that these nearly equidistant oscillations occurring in the vicinity of resonance may be used for making filter in micro wave frequency range.
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The authors are grateful to Dr. A. K. Singh and Dr. D. P. Singh for their continuous encouragement and supports in many ways.
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Sharma, Y., Prasad, S. & Singh, V. Dispersion behavior of electromagnetic wave near the resonance in 1D magnetized ferrite photonic crystals. Opt Quant Electron 50, 410 (2018). https://doi.org/10.1007/s11082-018-1677-8
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DOI: https://doi.org/10.1007/s11082-018-1677-8