English

Bergman kernel and hyperconvexity index

Complex Variables 2018-03-16 v3

Abstract

Let ΩCn\Omega\subset {\mathbb C}^n be a bounded domain with the hyperconvexity index α(Ω)>0\alpha(\Omega)>0. Let ϱ\varrho be the relative extremal function of a fixed closed ball in Ω\Omega and set μ:=ϱ(1+logϱ)1\mu:=|\varrho|(1+|\log|\varrho||)^{-1}, ν:=ϱ(1+logϱ)n\nu:=|\varrho|(1+|\log|\varrho||)^n. We obtain the following estimates for the Bergman kernel: (1) For every 0<α<α(Ω)0<\alpha<\alpha(\Omega) and 2p<2+2α(Ω)2nα(Ω)2\le p<2+\frac{2\alpha(\Omega)}{2n-\alpha(\Omega)}, there exists a constant C>0C>0 such that ΩKΩ(,w)KΩ(w)pCμ(w)(p2)nα\int_\Omega |\frac{K_\Omega(\cdot,w)}{\sqrt{K_\Omega(w)}}|^{p}\le C |\mu(w)|^{-\frac{(p-2) n}\alpha} for all wΩw\in \Omega. (2) For every 0<r<10<r<1, there exists a constant C>0C>0 such that KΩ(z,w)2KΩ(z)KΩ(w)C(min{ν(z)μ(w),ν(w)μ(z)})r \frac{|K_\Omega(z,w)|^2}{K_\Omega(z)K_\Omega(w)}\le C (\min\{\frac{\nu(z)}{\mu(w)},\frac{\nu(w)}{\mu(z)}\})^r for all z,wΩz,w\in \Omega. Various application of these estimates are given.

Keywords

Cite

@article{arxiv.1610.07016,
  title  = {Bergman kernel and hyperconvexity index},
  author = {Bo-Yong Chen},
  journal= {arXiv preprint arXiv:1610.07016},
  year   = {2018}
}

Comments

Minor changes. To appear in Analysis & PDE

R2 v1 2026-06-22T16:28:23.568Z