• Title of article

    variational principles and solitary wave solutions of generalized ‎nonlinear schrödinger equation in the ocean

  • Author/Authors

    liu, meng-zhu national university of defense technology - college of meteorology and oceanography, changsha, china , cao, xiao-qun national university of defense technology - college of meteorology and oceanography, college of computer, changsha, china , zhu, xiao-qian national university of defense technology - college of meteorology and oceanography, college of computer, changsha, china , liu, bai-nian national university of defense technology - college of meteorology and oceanography, college of computer, changsha, china , peng, ke-cheng national university of defense technology - college of meteorology and oceanography, changsha, china

  • From page
    1639
  • To page
    1648
  • Abstract
    internal solitary waves are very common physical phenomena in the ocean, which play an important role in the transport of marine matter, momentum and energy. because the generalized nonlinear schrödinger equation can well explain the effects of nonlinearity and dispersion in the ocean, it is more suitable for describing the deepsea internal wave propagation and evolution than other mathematical models. at first, by designing skillfully the trial-lagrange functional, different kinds of variational principles are successfully established for a generalized nonlinear schrödinger equation by the semi-inverse method. then, the constructed variational principles are proved correct by minimizing the functionals with the calculus of variations. furthermore, some kinds of internal solitary wave solutions are obtained and demonstrated by semi-inverse variational principle for the generalized nonlinear schrödinger equation.
  • Keywords
    generalized nonlinear schrödinger equation , semi , inverse method , variational principle , internal solitary waves
  • Journal title
    Journal of Applied and Computational Mechanics
  • Journal title
    Journal of Applied and Computational Mechanics
  • Record number

    2652871