Ground States of Attractive Bose Gases in Rotating Anharmonic Traps

TL;DR

This paper investigates the ground states of attractive Bose gases in rotating anharmonic traps, revealing conditions under which these states lack vortices near the critical interaction strength, with detailed energy analysis.

Contribution

It provides a refined analysis of ground states in rotating anharmonic traps, establishing vortex absence in certain regions as the interaction approaches the critical value.

Findings

Ground states exist for interaction strength 0<a<a*

No vortices are present in a specific region near the trap center as a approaches a*

The analysis applies to particular trap parameters and rotation speeds

Abstract

This paper is concerned with ground states of attractive Bose gases confined in an anharmonic trap $V(x)=\omega(|x|^2+k|x|^4)$ rotating at the velocity $\Omega>0$, where $\omega>0$ denotes the trapping frequency, and $k>0$ represents the strength of the quartic term. It is known that for any $\Omega>0$, ground states exist in such traps if and only if $0<a<a^*$, where $a^*:=\|Q\|^{2}_{2}$ and $Q>0$ is the unique positive solution of $\Delta Q-Q+Q^{3}=0$ in $\mathbb{R}^2$. By analyzing the refined energies and expansions of ground states, we prove that there exists a constant $C>0$, independent of $0<a<a^*$, such that ground states do not have any vortex in the region $R(a):=\big\{x\in\mathbb{R}^2:\, |x|\leq C(a^*-a)^{-\frac{1-6\beta}{20}}\big\}$ as $a\nearrow a^*$, for the case where $\omega=\frac{3\Omega^2}{4}$, $k=\frac{1}{6}$, and $\Omega=C_0(a^*-a)^{-\beta}$ varies for some $\beta\in [0,\frac{1}{6})$ and $C_0>0$.