Cartan-Thullen theorem for a Cn-holomorphic function and a related problem

Abstract

Cartan-Thullen theorem is a basic one in the theory of analytic functions of several complex variables. It states that for any open set U of Ck, the following conditions are equivalent: (a) U is a domain of existence, (b) U is a domain of holomorphy and (c) U is holomorphically convex. On the other hand, when f \, (\, =(f1,f2,·s,fn)\, ) is a Cn-valued function on an open set U of Ck1× Ck2×·s× Ckn, f is said to be Cn-analytic, if f is complex analytic and for any i and j, i=j implies ∂ fi∂ zj=0. Here, (z1,z2,·s,zn) ∈ Ck1× Ck2×·s× Ckn holds. We note that a Cn-analytic mapping and a Cn-analytic manifold can be easily defined. In this paper, we show an analogue of Cartan-Thullen theorem for a Cn-analytic function. For n=1, it gives Cartan-Thullen theorem itself. Our proof is almost the same as Cartan-Thullen theorem. Thus, our generalization seems to be natural. On the other hand, our result is partial, because we do not answer the following question. That is, does a connected open Cn-holomorphically convex set U exist such that U is not the direct product of any holomorphically convex sets U1, U2, ·s, Un-1 and Un ? As a corollary of our generalization, we give the following partial result. If U is convex, then U is the direct product of some holomorphically convex sets. Also, f is said to be Cn-triangular, if f is complex analytic and for any i and j, i<j implies ∂ fi∂ zj=0. Kasuya suggested that a Cn-analytic manifold and a Cn-triangular manifold might, for example, be related to a holomorphic web and a holomorphic foliation.