Strong Resonance of Light in a Cantor Set
Abstract
The propagation of an electromagnetic wave in a one-dimensional fractal object, the Cantor set, is studied. The transfer matrix of the wave amplitude is formulated and its renormalization transformation is analyzed. The focus is on resonant states in the Cantor set. In Cantor sets of higher generations, some of the resonant states closely approach the real axis of the wave number, leaving between them a wide region free of resonant states. As a result, wide regions of nearly total reflection appear with sharp peaks of the transmission coefficient beside them. It is also revealed that the electromagnetic wave is strongly enhanced and localized in the cavity of the Cantor set near the resonant frequency. The enhancement factor of the wave amplitude at the resonant frequency is approximately 6/|ηr|, where ηr is the imaginary part of the corresponding resonant eigenvalue. For example, a resonant state of the lifetime τr=4.3ms and of the enhancement factor M=7.8×107 is found at the resonant frequency ωr=367GHz for the Cantor set of the fourth generation of length L=10cm made of a medium of the dielectric constant ε=10.
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