English

Viscosity solutions to complex Hessian equations

Complex Variables 2013-02-07 v3 Analysis of PDEs Differential Geometry

Abstract

We study viscosity solutions to complex hessian equations. In the local case, we consider Ω\Omega a bounded domain in Cn,\mathbb{C}^n, β\beta the standard K\"{a}hler form in Cn\mathcal{C}^n and 1mn.1\leq m\leq n. Under some suitable conditions on F,gF, g, we prove that the equation (ddcφ)mβnm=F(x,φ)βn, \f=g(dd^c \varphi)^m\wedge\beta^{n-m}=F(x,\varphi)\beta^n,\ \f=g on \pO\pO admits a unique viscosity solution modulo the existence of subsolution and supersolution. If moreover, the datum are H\"{o}lder continuous then so is the solution. In the global case, let (X,ω)(X,\omega) be a compact hermitian homogeneous manifold where ω\omega is an invariant hermitian metric (not necessarily K\"{a}hler). We prove that the equation (ω+ddcφ)mωnm=F(x,φ)ωn(\omega+dd^c\varphi)^m\wedge\omega^{n-m}=F(x,\varphi)\omega^n has a unique viscosity solution under some natural conditions on F.F.

Cite

@article{arxiv.1209.5343,
  title  = {Viscosity solutions to complex Hessian equations},
  author = {Lu Hoang Chinh},
  journal= {arXiv preprint arXiv:1209.5343},
  year   = {2013}
}

Comments

fix typos

R2 v1 2026-06-21T22:10:11.970Z