English

Gelfand problem and Hemisphere rigidity

Differential Geometry 2022-07-12 v3 Analysis of PDEs

Abstract

We give an interpretation of the hemisphere rigidity theorem of Hang-Wang in the framework of Gelfand problem. More precisely, Hang-Wang showed that for a metric gg conformal to the standard metric g0g_0 on S+nS^{n}_{+} with Rn(n1)R\geq n(n-1) and whose boundary coincides with g0S+ng_0|_{\partial S^{n}_{+}}, then g=g0g=g_0. This is related to the classical Gelfand problem, which investigates Δu=λg(u)-\Delta u=\lambda g(u) for certain nonlinearity gg in a bounded region ΩRn\Omega \subset \mathbb{R}^n subject to the Dirichlet boundary condition. It is well-known that there exists an extremal λ\lambda^{*}, such that for λ>λ\lambda>\lambda^{*}, the above equation does not admit any solution. Interestingly, Hang-Wang's hemisphere rigidity theorem yields a precise value for λ\lambda^{*} for g(u)=e2ug(u)=e^{2u} when n=2n=2 and g(u)=(1+u)n+2n2g(u)=(1+u)^{\frac{n+2}{n-2}} for n3n\geq 3. We attempt to generalize the hemisphere rigidity theorem under QQ curvature lower bound and fit this into the interpretation of fourth order Gelfand problem for bi-Laplacian with conformal nonlinearity.

Keywords

Cite

@article{arxiv.2102.10360,
  title  = {Gelfand problem and Hemisphere rigidity},
  author = {Mijia Lai and Wei Wei},
  journal= {arXiv preprint arXiv:2102.10360},
  year   = {2022}
}

Comments

We re-built the structure of the paper

R2 v1 2026-06-23T23:21:22.230Z