Normalized Semiclassical Solutions to Magnetic Schrödinger-Poisson Systems with Critical Local and Nonlocal Interactions

Abstract

We study the existence, multiplicity, and concentration of normalized semiclassical states for a magnetic Schrödinger--Poisson system in R3 featuring both the Sobolev-critical local nonlinearity |u|4u and a critical nonlocal Poisson interaction. The problem is considered under the prescribed mass constraint ∫R3|u|2\,dx=a23, where a>0 denotes the prescribed mass and >0 is the semiclassical parameter. By combining constrained variational methods, a suitable penalization scheme, concentration--compactness arguments, and Ljusternik--Schnirelmann theory, we first prove the existence of a normalized semiclassical solution for sufficiently small a and . We then establish a multiplicity result showing that, for every sufficiently small >0, the number of distinct normalized solutions is bounded from below by the Ljusternik--Schnirelmann category of the minimum set \[ M = \x∈R3:V(x)=R3V\. \] Finally, we describe the semiclassical concentration phenomenon by showing that the maximum points of the resulting solutions approach M as 0.

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