In mathematics, in the theory of functions of several complex variables, a domain of holomorphy is a domain which is maximal in the sense that there exists a holomorphic function on this domain which cannot be extended to a bigger domain.

The sets in the definition.

Formally, an open set in the n-dimensional complex space is called a domain of holomorphy if there do not exist non-empty open sets and where is connected, and such that for every holomorphic function on there exists a holomorphic function on with on

In the case, every open set is a domain of holomorphy: we can define a holomorphic function with zeros accumulating everywhere on the boundary of the domain, which must then be a natural boundary for a domain of definition of its reciprocal. For this is no longer true, as it follows from Hartogs' lemma.

Equivalent conditions

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For a domain   the following conditions are equivalent:

  1.   is a domain of holomorphy
  2.   is holomorphically convex
  3.   is pseudoconvex
  4.   is Levi convex - for every sequence   of analytic compact surfaces such that   for some set   we have   (  cannot be "touched from inside" by a sequence of analytic surfaces)
  5.   has local Levi property - for every point   there exist a neighbourhood   of   and   holomorphic on   such that   cannot be extended to any neighbourhood of  

Implications   are standard results (for  , see Oka's lemma). The main difficulty lies in proving  , i.e. constructing a global holomorphic function which admits no extension from non-extendable functions defined only locally. This is called the Levi problem (after E. E. Levi) and was first solved by Kiyoshi Oka, and then by Lars Hörmander using methods from functional analysis and partial differential equations (a consequence of  -problem).

Properties

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  • If   are domains of holomorphy, then their intersection   is also a domain of holomorphy.
  • If   is an ascending sequence of domains of holomorphy, then their union   is also a domain of holomorphy (see Behnke-Stein theorem).
  • If   and   are domains of holomorphy, then   is a domain of holomorphy.
  • The first Cousin problem is always solvable in a domain of holomorphy; this is also true, with additional topological assumptions, for the second Cousin problem.

See also

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References

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  • Steven G. Krantz. Function Theory of Several Complex Variables, AMS Chelsea Publishing, Providence, Rhode Island, 1992.
  • Boris Vladimirovich Shabat, Introduction to Complex Analysis, AMS, 1992

This article incorporates material from Domain of holomorphy on PlanetMath, which is licensed under the Creative Commons Attribution/Share-Alike License.