Abstract EN:

We study the structure of radially symmetric standing waves for the nonlinear Schrodinger equation with harmonic potential. This equation arises in a wide variety of applications and is known as the Gross-Pitaevskii equation in the context of Bose-Einstein condensates with parabolic traps. Both global and local bifurcation behavior are determined showing the existence of infinitely symmetric modes of the equation. In particular, our theory provides a theoretical proof of the existence of soliton with prescribed numbers of zeros depending on the frequency of wave which was recently observed by numerical simulations. After a theoretical study of the three cases, numerical computations are finally presented in order to provide an illustration of the theoretical results that have been obtained and also to the to address some problems for which only few results are known, including the stability of excited states and the multiplicity of solutions vanishing k times in the critical and supercritical case (Brezis-Nirenberg phenomenon)