The project investigates coherent propagation of pulses in nonlinear periodic structures, e.g. photonic crystals, with an arbitrarily large contrast of the periodicity. Moving pulses are mathematically relatively well understood in periodic structures with an asymptotically small contrast. True physical structure have, however, a fixed finite contrast. The mathematical analysis for this case is markedly more difficult.In particular, for the one dimensional cubically nonlinear Schrödinger equation and for the cubically nonlinear wave equation we will study moving solitary waves (moving gap solitons) in narrow spectral gaps which open by a perturbation of a periodic structure with a transversal crossing of spectral band functions. The amplitude of the perturbation, or equivalently the width of the gap, will play the role of a small asymptotic parameter. An example of a periodic medium featuring transversal crossings of spectral functions in the band structure is one described by a finite band potential. The transversality is expected to lead to the existence of a whole family of gap solitons with an interval of velocities which are independent of the asymptotic parameter. This is in contrast with the standard case of structure with an arbitrary contrast, where only asymptotically slow gap solitons are known asymptotically close to the spectrum.Firstly, an asymptotic envelope approximation of gap solitons via coupled mode equations will be given. The asymptotics will then be rigorously justified and the approximation error estimated for large but finite time intervals. Numerical computations will then corroborate the analysis, show examples of gap solitons and check the asymptotic convergence rates. The second, and more challenging, part will deal with the existence of exact moving generalized breathers of the two equations. These breathers are moving pulses, whose shape changes periodically in space and time. Based on related existing results only generalized breathers are expected, i.e. such pulses whose profiles are very close to localized ones on very large but finite spatial intervals. It is, once again, the aim to produce a family of breathers with an interval of velocities.

DFG Programme Research Grants

Participating Person Professor Dr. Guido Schneider