APS March Meeting 2016
Volume 61, Number 2
Monday–Friday, March 14–18, 2016;
Baltimore, Maryland
Session C12: Intrinsic Localized Modes: Recent Developments and Future Perspectives
2:30 PM–5:30 PM,
Monday, March 14, 2016
Room: 308
Sponsoring
Units:
GSNP GSOFT
Chair: David Campbell, Boston University
Abstract ID: BAPS.2016.MAR.C12.5
Abstract: C12.00005 : Intrinsic Localized Modes in Optical Photonic Lattices and Arrays
4:54 PM–5:30 PM
Preview Abstract
Abstract
Author:
Demetrios Christodoulides
(CREOL-College of Optics and Photonics, UCF)
Discretizing light behavior requires optical elements that can confine
optical energy at distinct sites. One possible scenario in implementing such
arrangements is to store energy within low loss high Q-microcavities and
then allow photon exchange between such components in time. This scheme
requires high-contrast dielectric elements that became available with the
advent of photonic crystal technologies. Another possible avenue where such
light discretization can be directly observed and studied is that based on
evanescently coupled waveguide arrays. As indicated in several studies,
discrete systems open up whole new directions in terms of modifying light
transport properties. One such example is that of discrete solitons. By
nature, discrete solitons represent self-trapped wavepackets in nonlinear
periodic structures and result from the interplay between lattice
diffraction (or dispersion) and material nonlinearity. In optics, this class
of self-localized states has been successfully observed in both one- and
two-dimensional nonlinear waveguide arrays. In recent years such photonic
lattices have been implemented or induced in a variety of material systems,
including those with cubic (Kerr), quadratic, photorefractive, and
liquid-crystal nonlinearities. In all cases the underlying periodicity or
discreteness can lead to new families of optical solitons that have no
counterpart whatsoever in continuous systems. Interestingly, these results
paved the way for observations in other physical systems obeying similar
evolution equations like Bose-Einstein condensates. New developments in
laser writing ultrashort femtosecond laser pulses, now allow the realization
of all-optical switching networks in fully 3D environments using nonlinear
discrete optics. Using this approach all-optical routing can be achieved
using blocking operations. The spatio-temporal evolution of optical pulses
in both normally and anomalously dispersive arrays can lead to novel schemes
for mode-locking and pulse compression. A strong signature of discrete
X-wave formation was also demonstrated in such structures. In the last few
years, Anderson localization was unequivocally observed in array systems
where the transition from ballistic transport to diffusive, and the
cross-over to Anderson localization was studied as a function of disorder
and nonlinearity. In recent studies synthetic lattices exhibiting
parity-time (PT) symmetry were also considered. The interplay of gain and
loss in this latter family of structures leads to counterintuitive
characteristics and behavior such as non-reciprocal propagation and power
oscillations. The realization of discrete array systems at su-bwavelenth
scales is another important direction that is nowadays intensively pursued.
References
1. D. N. Christodoulides, F. Lederer, and Y. Silberberg, Nature 424, 817-
823 (2003).
2. F. Lederer, G. I. Stegeman, D. N. Christodoulides, G. Assanto, M. Segev
and Y. Silberberg, Phys. Reports 463, 1-126 (2008).
3. M Wimmer, A Regensburger, MA Miri, C. Bersch, D.N Christodoulides, and U.
Peschel, "Observation of optical solitons in PT-symmetric lattices" Nature
Communications 6, 7782 (2015).
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2016.MAR.C12.5