The Ground State of a Cubic-quintic Nonlinear Schr\"odinger Equation with Radial Potential in the Thomas-Fermi Limit

Abstract

We focus on the ground state of the cubic-quintic nonlinear Schr\"odinger energy functional gather* aligned E()=12∫Rd(|∇ |2+V(x)||2)\,dx 14∫Rd||4\,dx +16∫Rd||6\,dx, (d=1,2,3) aligned gather* under the mass constraint ∫Rd||2\,dx=N, where N can be viewed as particle number, and V(x) behaves like C|x|p (p≥ 2) as |x|→ +∞, including the harmonic potential. When N→ +∞, we show that up to a suitable scaling the ground state N would convergence strongly in some Lq(Rd) space to a Thomas-Fermi minimizer, this limit can be referred to as the Thomas-Fermi limit. The limit Thomas-Fermi profile has compact support, given by uTF(x)=[μTF-C0|x|p]14+, where μTF is a suitable Lagrange multiplier with exact value. We find that, similar to the asymptotic analysis in [J. Funct. Anal. 260 (2011), 2387-2406.] and [Arch. Ration. Mech. Anal. 217 (2015), 439-523.] for Gross-Pitaevskii energy in the Thomas-Fermi limit where a small parameter tends to 0, there also has a steep corner layer near the boundary of compact support of uTF(x), in which the ground state has irregular behavior as N→ +∞. Finally, we establish a new energy method to obtain the L∞-convergence rates of ground states N inside the corner layer and outside corner layer respectively, this method may be applicable to other general nonlinearities.

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