Convergence analysis of Sobolev Gradient flows for the rotating Gross-Pitaevskii energy functional
By: Chen Zhang , Patrick Henning , Mahima Yadav and more
Potential Business Impact:
Makes super-cold atom clouds spin predictably.
This paper studies the numerical approximation of the ground state of rotating Bose--Einstein condensates, formulated as the minimization of the Gross--Pitaevskii energy functional under a mass conservation constraint. To solve this problem, we consider three Sobolev gradient flow schemes: the $H_0^1$ scheme, the $a_0$ scheme, and the $a_u$ scheme. Convergence of these schemes in the non-rotating case was established by Chen et al., and the rotating $a_u$ scheme was analyzed in Henning et al. In this work, we prove the global convergence of the $H_0^1$ and $a_0$ schemes in the rotating case, and establish local linear convergence for all three schemes near the ground state. Numerical experiments confirm our theoretical findings.
Similar Papers
Convergence analysis of Sobolev Gradient flows for the rotating Gross-Pitaevskii energy functional
Numerical Analysis
Makes tiny frozen gas clouds spin better.
A gradient flow model for the Gross--Pitaevskii problem: Mathematical and numerical analysis
Numerical Analysis
Makes tiny particles in cold gas behave predictably.
On preconditioned Riemannian gradient methods for minimizing the Gross-Pitaevskii energy functional: algorithms, global convergence and optimal local convergence rate
Numerical Analysis
Makes computer simulations of spinning atoms faster.