• DocumentCode
    831598
  • Title

    Computational modeling of femtosecond optical solitons from Maxwell´s equations

  • Author

    Goorjian, Peter M. ; Taflove, Allen ; Joseph, Rose M. ; Hagness, Susan C.

  • Author_Institution
    NASA Ames Res. Center, Moffett Field, CA, USA
  • Volume
    28
  • Issue
    10
  • fYear
    1992
  • fDate
    10/1/1992 12:00:00 AM
  • Firstpage
    2416
  • Lastpage
    2422
  • Abstract
    An algorithm is developed that permits the direct time integration of full-vector nonlinear Maxwell´s equations. This capability permits the modeling of both linear and nonlinear instantaneous and dispersive effects in the electric polarization in material media. The modeling of the optical carrier is retained. The fundamental innovation is to notice that it is possible to treat the linear and nonlinear convolution integrals, which describe the dispersion, as new dependent variables. A coupled system of nonlinear second-order ordinary differential equations can then be derived for the linear and nonlinear convolution integrals, by differentiating them in the time domain. These equations, together with Maxwell´s equations, are solved to determine the electromagnetic fields in nonlinear dispersive media. Results are presented of calculations in one dimension of the propagation and collision of femtosecond electromagnetic solitons that retain the optical carrier, taking into account the Kerr and Raman interactions
  • Keywords
    Maxwell equations; integration; nonlinear differential equations; optical dispersion; optical solitons; Kerr interactions; Raman interactions; algorithm; computational modelling; coupled system; direct time integration; dispersive effects; electric polarization; electromagnetic fields; femtosecond optical solitons; full-vector nonlinear Maxwell´s equations; linear convolution integrals; nonlinear convolution integrals; nonlinear dispersive media; nonlinear second-order ordinary differential equations; one dimension; optical carrier; time domain; Computational modeling; Convolution; Dispersion; Integral equations; Maxwell equations; Nonlinear optics; Optical materials; Optical polarization; Optical solitons; Ultrafast optics;
  • fLanguage
    English
  • Journal_Title
    Quantum Electronics, IEEE Journal of
  • Publisher
    ieee
  • ISSN
    0018-9197
  • Type

    jour

  • DOI
    10.1109/3.159548
  • Filename
    159548