Construction of 2-solitons with logarithmic distance for the one-dimensional cubic Schrodinger system

Abstract

We consider a system of coupled cubic Schr\"odinger equations in one space dimension equation* cases i ∂t u + ∂x2 u +(|u|2 + ω |v|2) u =0\\ i ∂t v + ∂x2 v+ (|v|2 + ω |u|2) v=0 cases (t,x)∈ R× R, equation* in the non-integrable case 0 < ω < 1. First, we justify the existence of a symmetric 2-solitary wave with logarithmic distance, more precisely a solution of the system satisfying \[ t +∞\| pmatrix u(t) \\ v(t)pmatrix - pmatrix eitQ (· - 12 ( t) - 14 t) \\ eitQ (· + 12 ( t) + 14 t)pmatrix\|H1× H1 = 0\] where Q = 2 sech is the explicit solution of Q'' - Q + Q3 = 0 and >0 is a constant. This result extends to the non-integrable case the existence of symmetric 2-solitons with logarithmic distance known in the integrable case ω=0 and ω=1. Such strongly interacting symmetric 2-solitary waves were also previously constructed for the non-integrable scalar nonlinear Schr\"odinger equation in any space dimension and for any energy-subcritical power nonlinearity. Second, under the conditions 0<c<1 and 0<ω < 12 c(c+1), we construct solutions of the system satisfying \[ t +∞\| pmatrixu(t) \\ v(t)pmatrix - pmatrixei c2 tQc (· - 1(c+1)c (c t) ) \\ ei t Q (· + 1c+1 (c t))pmatrix \|H1× H1=0\] where Qc(x)=cQ(cx) and c>0 is a constant. Such logarithmic regime with non-symmetric solitons does not exist in the integrable cases ω=0 and ω=1 and is still unknown in the non-integrable scalar case.