English

Existence for Stable Rotating Star-Planet Systems

Analysis of PDEs 2026-04-22 v2 Mathematical Physics math.MP

Abstract

This paper investigates the existence and properties of stable, uniformly rotating star-planet systems, i.e. mass ratio is sufficiently small. It is modeled by the Euler-Poisson equations. Following the framework established by McCann for binary stars \cite{McC06}, we adopt a variational approach, and prove the existence of local energy minimizers with respect to the Wasserstein LL^\infty metric, under the assumed equation of state P(ρ)=KργP(\rho)=K\rho^\gamma and under the condition that the mass ratio mm is sufficiently small, corresponding to a star-planet system. Such minimizers correspond to solutions of the Euler-Poisson system. We consider two cases. For γ>2\gamma > 2, we not only prove existence but also show, via scaling arguments, that the radii (to be precise, the bounds of the supports of the minimizers) tend to zero. For 32<γ2\frac{3}{2} < \gamma \leq 2, we estimate an upper bound for the (potential) expansion rates of the radii, and it turns out that the existence result remains valid in this case as well. Finally, we provide estimates for the distances between different connected components of supports of minimizers and propose a conjecture regarding the number of connected components.

Keywords

Cite

@article{arxiv.2602.02761,
  title  = {Existence for Stable Rotating Star-Planet Systems},
  author = {Hangsheng Chen},
  journal= {arXiv preprint arXiv:2602.02761},
  year   = {2026}
}

Comments

Minor revisions in formatting, exposition, and grammar. Remarks and appendix updated. 45 pages total. Comments are welcome

R2 v1 2026-07-01T09:32:57.891Z