Solutions of multi-component fractional symmetric systems

Abstract

We study the following elliptic system concerning the fractional Laplacian operator (- ) si ui = Hi ( u1,·s,um) \ \ in\ \ Rn, when 0<si<1, ui: Rn R and Hi belongs to C1,γ(Rm) for γ > (0,1-2 \si \) for 1 i m. The above system is called symmetric when the matrix H=(∂j Hi(u1,·s,um))i,j=1m is symmetric. The notion of symmetric systems seems crucial to study this system with a general nonlinearity H=(Hi)i=1m. We establish De Giorgi type results for stable and H-monotone solutions of symmetric systems in lower dimensions that is either n=2 and 0<si<1 or n=3 and 1/2 \si\<1. The case that n=3 and at least one of parameters si belongs to (0,1/2) remains open as well as the case n 4. Applying a geometric Poincar\'e inequality, we conclude that gradients of components of solutions are parallel in lower dimensions when the system is coupled. More precisely, we show that the angle between vectors ∇ ui and ∇ uj is exactly (|∂j Hi(u)|/∂j Hi(u)). In addition, we provide Hamiltonian identities, monotonicity formulae and Liouville theorems. Lastly, we apply some of our main results to a two-component nonlinear Schr\"odinger system, that is a particular case of the above system, and we prove Liouville theorems and monotonicity formulae.