Blow-up criteria for the 3D cubic nonlinear Schrödinger equation

We consider solutions u to the 3D nonlinear Schrodinger equation i∂tu + Δu + |u|2u = 0. In particular, we are interested in finding criteria on the initial data u0 that predict the asymptotic behaviour of u(t), e.g., whether u(t) blows up in finite time, exists globally in time but behaves like a linear solution for large times (scatters), or exists globally in time but does not scatter. This question has been resolved (at least for H1 data) (Duyckaerts–Holmer–Roudenko) if M[u]E[u] ≤ M[Q]E[Q], where M[u] and E[u] denote the mass and energy of u and Q denotes the ground state solution to −Q + ΔQ + |Q|2Q = 0. Here we consider the complementary case M[u]E[u] > M[Q]E[Q]. In the first (analytical) part of the paper, we present a result due to Lushnikov, based on the virial identity and the generalized uncertainty principle, giving a sufficient condition for blow-up. By replacing the uncertainty principle in his argument with an interpolation-type inequality, we obtain a new blow-up condition that in some cases improves upon Lushnikov's condition. Our approach also allows for an adaptation to radial infinite-variance initial data that has a conceptual interpretation: for real-valued initial data, if a certain fraction of the mass is contained within the ball of radius M[u], then blow up occurs. We also show analytically (if one takes the numerically computed value of ) that there exist Gaussian initial data u0 with negative quadratic phase such that but the solution u(t) blows up. In the second (numerical) part of the paper, we examine several different classes of initial data—Gaussian, super Gaussian, off-centred Gaussian, and oscillatory Gaussian—and for each class give the theoretical predictions for scattering or blow-up provided by the above theorems as well as the results of numerical simulation. We find that depending upon the form of the initial conditions, any of the three analytical criteria for blow-up can be optimal. We formulate several conjectures, among them that for real initial data, the quantity provides the threshold for scattering.

[1]  V. Zakharov,et al.  Exact Theory of Two-dimensional Self-focusing and One-dimensional Self-modulation of Waves in Nonlinear Media , 1970 .

[2]  T. Cazenave Semilinear Schrodinger Equations , 2003 .

[3]  V. I. Talanov,et al.  Focusing of Light in Cubic Media , 1970 .

[4]  Vladimir E. Zakharov,et al.  Computer simulation of wave collapses in the nonlinear Schro¨dinger equation , 1991 .

[5]  G. Fibich Some Modern Aspects of Self-focusing Theory , 2009 .

[6]  Sergei K. Turitsyn,et al.  Sharper criteria for the wave collapse , 1994 .

[7]  M. Beceanu A Critical Centre-Stable Manifold for Schroedinger's Equation in R^3 , 2009, 0909.1180.

[8]  P. Raphaël,et al.  Blow up of the critical norm for some radial L2 super critical nonlinear Schrödinger equations , 2006, math/0605378.

[9]  N. Gavish,et al.  Singular ring solutions of critical and supercritical nonlinear Schrödinger equations , 2007 .

[10]  Jacqueline E. Barab,et al.  Nonexistence of asymptotically free solutions for a nonlinear Schrödinger equation , 1984 .

[11]  Walter A. Strauss,et al.  Existence of solitary waves in higher dimensions , 1977 .

[12]  T. Tao Nonlinear dispersive equations : local and global analysis , 2006 .

[13]  Carl E. Wieman,et al.  Dynamics of collapsing and exploding Bose–Einstein condensates , 2001, Nature.

[14]  V. Zakharov Collapse of Langmuir Waves , 1972 .

[15]  T. Cazenave,et al.  Rapidly decaying solutions of the nonlinear Schrödinger equation , 1992 .

[16]  A Sharp Condition for Scattering of the Radial 3D Cubic Nonlinear Schrödinger Equation , 2007, math/0703235.

[17]  P. Lushnikov Dynamic criterion for collapse , 1995 .

[18]  S. Roudenko,et al.  Threshold solutions for the focusing 3D cubic Schrödinger equation , 2008, 0806.1752.

[19]  C. Sulem,et al.  The nonlinear Schrödinger equation : self-focusing and wave collapse , 2004 .

[20]  J. Holmer,et al.  Divergence of Infinite-Variance Nonradial Solutions to the 3D NLS Equation , 2009, 0906.0203.

[21]  Maciej Zworski,et al.  Fast Soliton Scattering by Delta Impurities , 2007 .

[22]  F. Dalfovo,et al.  Theory of Bose-Einstein condensation in trapped gases , 1998, cond-mat/9806038.

[23]  S. N. Vlasov,et al.  Averaged description of wave beams in linear and nonlinear media (the method of moments) , 1971 .

[24]  Direct observation of growth and collapse of a Bose–Einstein condensate with attractive interactions , 2000, Nature.

[25]  Nakao Hayashi,et al.  Asymptotics for large time of solutions to the nonlinear Schrödinger and Hartree equations , 1998 .

[26]  M. Beceanu A Critical Centre-Stable Manifold for the Cubic Focusing Schroedinger Equation in Three Dimensions , 2009, 0902.1643.

[27]  J. Holmer,et al.  Scattering for the non-radial 3D cubic nonlinear Schroedinger equation , 2007, 0710.3630.

[28]  R. Glassey On the blowing up of solutions to the Cauchy problem for nonlinear Schrödinger equations , 1977 .

[29]  N. Gavish,et al.  New singular solutions of the nonlinear Schrödinger equation , 2005 .

[30]  J. Holmer,et al.  On Blow-up Solutions to the 3D Cubic Nonlinear Schrödinger Equation , 2010 .

[31]  Michael I. Weinstein,et al.  On the structure and formation of singularities in solutions to nonlinear dispersive evolution equations , 1986 .

[32]  Catherine Sulem,et al.  The nonlinear Schrödinger equation , 2012 .

[33]  J. K. Shaw,et al.  On the Eigenvalues of Zakharov-Shabat Systems , 2003, SIAM J. Math. Anal..

[34]  Collapsing dynamics of attractive Bose–Einstein condensates , 2000, physics/0012004.

[35]  S. Manakov,et al.  Asymptotic behavior of non-linear wave systems integrated by the inverse scattering method , 1996 .

[36]  P. Deift,et al.  Long‐time asymptotics for solutions of the NLS equation with initial data in a weighted Sobolev space , 2002, math/0206222.

[37]  M. Weinstein Nonlinear Schrödinger equations and sharp interpolation estimates , 1983 .