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Modeling light trapping in nonlinear photonic structures

Modeling light trapping in nonlinear photonic structures. Alejandro Aceves Department of Mathematics and Statistics The University of New Mexico. Work in collaboration with Tomas Dohnal, ETH Zurich Center for Nonlinear Mathematics and Applications, AIMS, Poitiers, June 2006.

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Modeling light trapping in nonlinear photonic structures

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  1. Modeling light trapping in nonlinear photonic structures Alejandro Aceves Department of Mathematics and Statistics The University of New Mexico Work in collaboration with Tomas Dohnal, ETH Zurich Center for Nonlinear Mathematics and Applications, AIMS, Poitiers, June 2006

  2. What is a nonlinear photonic structure • It is an “engineered” optical medium with periodic properties. • Photonic structures are built to manipulate light (slow light, light localization, trap light) • I’ll show some examples, but this talk will concentrate on 2-dim periodic waveguides

  3. Photonic structures with periodic index of refraction in the direction of propagation • 1D periodic structures – • photonic crystal fibers • fiber gratings • Gap solitons (Theory: A.A, S. Wabnitz, Exp: Eggleton, Slusher (Bell Labs)) • Fiber gratings with defects – stopping of light (Goodman, Slusher, Weinstein 2002) • 2D periodic structures – waveguide gratings (T. Dohnal, A.A) • x- uniform medium with a z- grating • z- grating, guiding in x • 2D soliton-like bullets • Interactions of 2 bullets • waveguide gratings with defects

  4. Motivation of study We take advantage of periodic structures and nonlinear effects to propose new stable and robust systems relevant to optical systems. • Periodic structure - material with a periodically varying index of refraction (“grating”) • Nonlinearity - dependence of the refractive index on the intensity of the electric field • (Kerr nonlinearity) • The effects we seek: • existence of stable localized solutions – solitary waves, solitons • short formation lengths of these stable pulses • possibility to control the pulses – speed, direction (2D, 3D) • Prospective applications: • rerouting of pulses • optical memory • low-loss bending of light

  5. Nonlinear optics in waveguides • Starting point : Maxwell’s equations • Separation of variables, transverse mode satisfies eigenvalue problem and envelope satisfies nonlinear wave equation derived from asymptotic theory This is the nonlinear Schroedinger equation known to describe optical pulses in fibers and light beams in waveguides

  6. Solitons in homogeneous systems Elastic soliton interaction in the Nonlinear Schroedinger Eq.

  7. Optical fiber gratings

  8. 1-dim Coupled Mode Equations Gap solitons exist. Velocity proportional to amplitude mismatch Between forward and backward envelopes.

  9. 1D Gap Soliton

  10. y z x Waveguide gratings – 2Din collaboration with Tomas Dohnal (currently a postdoc at ETH) • Assumptions: • dynamics in y arrested by a fixed n(y) profile • xy-normal incidence of pulses • characteristic length scales of coupling, • nonlinearity and diffraction are in balance BARE 2D WAVEGUIDE - 2D NL Schrödinger equation - collapse phenomena: point blow-up WAVEGUIDE GRATING - 2D CME - no collapse - possibility of localization

  11. Dispersion relation for coupled mode equations Close, but outside the gap Well approximated by the 2D NLSE + higher order corrections. Collapse arrest shown by Fibich, Ilan, A.A (2002). But dynamics is unstable Frequency gap region. We will study dynamics in this regime.

  12. advection diffraction coupling non-linearity Governing equations : 2D Coupled Mode Equations

  13. Stationary solutions via Newton’s iteration

  14. Stationary case I

  15. Stationary case I

  16. Nonexistence of minima of the Hamiltonian

  17. Defects in 1d gratings • Trapping of a gap soliton bullet in a defect. (this concept has been theoretically demonstrated by Goodman, Weinstein, Slusher for the 1-dim (fiber Bragg grating with a defect) case). Ref: R. Goodman et.al., JOSA B 19, 1635 (July 2002)

  18. non-linearity advection diffraction coupling defect Governing equations : 2D CME

  19. κ=const., V=0 (no defect): Moving gap soliton bullet

  20. 2-D version of resonant trapping

  21. Trapping into two defect modes 3 trapping cases (GS: ω(v=0) ≈ 0.96)

  22. Trapping into 2 modes (movie)

  23. 3 trapping cases (GS: ω(v=0) ≈ 0.96) • Trapping into one defect mode

  24. Trapping into 1 mode (movie)

  25. ← ALL FAR FROM RESONANCE 3 trapping cases (GS: ω(v=0) ≈ 0.96) • No trapping

  26. No trapping (movie)

  27. Finite dimensional approximation of the trapped dynamics Less energy trapped => better agreement

  28. Reflection from a “repelling” defect potential

  29. Reflection with a tilt, “bouncing” beam

  30. Conclusions • 2d nonlinear photonic structures show promising properties for quasi-stable propagation of “slow” light-bullets • With the addition of defects, we presented examples of resonant trapping • Research in line with other interesting schemes to slow down light for eventually having all optical logic devices (eg. buffers) • Work recently appeared in Studies in Applied Math (2005)

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