Asymptotic Sphere Concentration at Infinity for NLS with L2 Constraint
Abstract
We consider the nonlinear Schr\"odinger equation- u + V(x)\,u = a\,up + μ u in Rn, ∫Rn u2 = 1,modeling attractive Bose--Einstein condensates. For all dimensions n 2 and all exponents p>1, we prove the existence of normalized solutions whose L2-mass concentrates on spheres with radii diverging to infinity. In particular, the concentration set escapes to infinity rather than remaining on a fixed compact hypersurface, which makes our regime qualitatively different both from classical point-concentration phenomena and from concentrating profiles in unconstrained problems. Our approach combines a tailored finite-dimensional reduction with a blow-up analysis based on Pohozaev identities and, in this way, extends the two-dimensional mass-critical result for (n,p)=(2,3) obtained in Guo--Tian--Zhou (Calc.\ Var.\ Partial Differential Equations, 2022). The proof in that paper relies in an essential way on the two-dimensional structure and does not directly apply in higher dimensions, whereas here we develop a different approximation scheme and functional setting adapted to the high-dimensional sphere-at-infinity concentration regime.
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