2,858 research outputs found
Indifferent electromagnetic modes: bound states and topology
At zero energy the Dirac equation has interesting behaviour. The asymmetry in
the number of spin up and spin down modes is determined by the topology of both
space and the gauge field in which the system sits. An analogous phenomenon
also occurs in electromagnetism. Writing Maxwell's equations in a Dirac-like
form, we identify cases where a material parameter plays the role of energy. At
zero energy we thus find electromagnetic modes that are indifferent to local
changes in the material parameters, depending only on their asymptotic values
at infinity. We give several examples, and show that this theory has
implications for non-Hermitian media, where it can be used to construct
permittivity profiles that are either reflectionless, or act as coherent
perfect absorbers, or lasers.Comment: 10 pages, 6 figure
Unidirectional wave propagation in media with complex principal axes
In an anisotropic medium, the refractive index depends on the direction of
propagation. Zero index in a fixed direction implies a stretching of the wave
to uniformity along that axis, reducing the effective number of dimensions by
one. Here we investigate two dimensional gyrotropic media where the refractive
index is zero in a complex valued direction, finding that the wave becomes an
analytic function of a single complex variable z. For simply connected media
this analyticity implies unidirectional propagation of electromagnetic waves,
similar to the edge states that occur in photonic 'topological insulators'. For
a medium containing holes the propagation is no longer unidirectional. We
illustrate the sensitivity of the field to the topology of the space using an
exactly solvable example. To conclude we provide a generalization of
transformation optics where a complex coordinate transformations can be used to
relate ordinary anisotropic media to the recently highlighted gyrotropic ones
supporting one-way edge states.Comment: 21 pages, 4 figure
Transport Coefficients of Quark Gluon Plasma for Pure Gauge Models
The transport coefficients of quark gluon plasma are calculated on a lattice
16**3X8, with the pure gauge models. Matsubara Green's functions of energy
momentum tensors have very large fluctuations and about a few million MC sweeps
are needed to reduce the errors reasonably small in the case of the standard
action. They are much suppressed if Iwasaki's improved action is employed.
Preliminary results show that the transport coefficients roughly depend on the
coupling constant as a**(-3)(g) in the case of SU(2).Comment: Talk presented at LATTICE96(finite temperature), 3 pages in latex, 4
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