Plasmons and the electromagnetic response of nanowires
Author
Abstract
We present a theory of the nature of plasmons in nanowires along with the response of such systems to a
spatially uniform applied electric field in the plane perpendicular to the symmetry axis of the wire. We confine
our analysis to the electrostatic description of these properties and to modes with infinite wavelength parallel
to the wire’s symmetry axis. Our theory thus focuses on the limit where the linear dimensions of the cross
section are small compared to the wavelength of radiation that may illuminate the system. We derive integral
equations that involve only the electrostatic potential on the boundary of the wire for a wire of arbitrary cross
section. Once this is solved, a complete description of the potential may be generated. Companion equations
are obtained for the function that provides one with the lines of electric field in the system. The homogeneous
versions of these equations provide one with a means of finding the plasmon eigenfrequencies and eigenfunctions,
whereas the inhomogeneous equations allow one to generate the response of the nanowire to a spatially
uniform applied field. We present numerical studies of the plasmon normal modes and electromagnetic response
of nanowires of rectangular cross section, and we compare our results to experiments and to a calculation
done by other methods.
Patrocinador
The research of D.L.M. was supported by the U.S.
National Science Foundation under Grant No. CHE-
0802913. A.J. and R.E.A. also acknowledge support from
FONDECYT under Contract No. 1085028 Chile and from
the Millenium Science Nucleus “Basic and Applied Magnetism”
under Contract No. P06-022-F (Chile).
Identifier
URI: https://repositorio.uchile.cl/handle/2250/125359
DOI: DOI: 10.1103/PhysRevB.81.085422
Quote Item
PHYSICAL REVIEW B 81, 085422 (2010)
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