The toroidal dipole is a peculiar electromagnetic excitation that cannot be presented in terms of standard electric and magnetic multipoles. A static toroidal dipole has been shown to lead to violation of parity in atomic spectra and many other unusual electromagnetic phenomena. The existence of electromagnetic resonances of toroidal nature was experimentally demonstrated only recently, first in the microwave metamaterials, and then at optical frequencies, where they could be important in spectroscopy analysis of a wide class of media with constituents of toroidal symmetry, such as complex organic molecules, fullerenes, bacteriophages, etc. Despite the experimental progress in studying toroidal resonances, no direct link has yet been established between microscopic toroidal excitations and macroscopic scattering characteristics of the medium. To address this essential gap in the electromagnetic theory, we have developed an analytical approach for calculating the transmissivity and reflectivity of thin slabs of materials that exhibit toroidal dipolar excitations.
[1]
Milton Abramowitz,et al.
Handbook of Mathematical Functions with Formulas, Graphs, and Mathematical Tables
,
1964
.
[2]
D. A. Dunnett.
Classical Electrodynamics
,
2020,
Nature.
[3]
K. Haller.
Quantum Electrodynamics
,
1979,
Nature.
[4]
S. Lang,et al.
An Introduction to Fourier Analysis and Generalised Functions
,
1959
.
[5]
Andrew G. Glen,et al.
APPL
,
2001
.
[6]
최인후,et al.
13
,
1794,
Tao te Ching.
[7]
C. Bowden,et al.
Waves
,
2011
.
[8]
E. M. Lifshitz,et al.
Classical theory of fields
,
1952
.
[9]
D. Owen.
Handbook of Mathematical Functions with Formulas
,
1965
.
[10]
G. Arfken.
Mathematical Methods for Physicists
,
1967
.
[11]
J. Goodman.
Introduction to Fourier optics
,
1969
.