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In mathematics, a Siegel domain or Piatetski-Shapiro domain is a special open subset of
complex Complex commonly refers to: * Complexity, the behaviour of a system whose components interact in multiple ways so possible interactions are difficult to describe ** Complex system, a system composed of many components which may interact with each ...
affine space In mathematics, an affine space is a geometric structure that generalizes some of the properties of Euclidean spaces in such a way that these are independent of the concepts of distance and measure of angles, keeping only the properties relate ...
generalizing the
Siegel upper half plane In mathematics, the Siegel upper half-space of degree ''g'' (or genus ''g'') (also called the Siegel upper half-plane) is the set of ''g'' × ''g'' symmetric matrices over the complex numbers whose imaginary part is positive definite. It ...
studied by . They were introduced by in his study of bounded homogeneous domains.


Definitions

A Siegel domain of the first kind (or first type, or genus 1) is the open subset of C''m'' of elements ''z'' such that :\Im(z)\in V \, where ''V'' is an open convex cone in R''m''. These are special cases of
tube domain In mathematics, a tube domain is a generalization of the notion of a vertical strip (or half-plane) in the complex plane to several complex variables. A strip can be thought of as the collection of complex numbers whose real part lie in a given s ...
s. An example is the
Siegel upper half plane In mathematics, the Siegel upper half-space of degree ''g'' (or genus ''g'') (also called the Siegel upper half-plane) is the set of ''g'' × ''g'' symmetric matrices over the complex numbers whose imaginary part is positive definite. It ...
, where ''V''⊂R''k''(''k'' + 1)/2 is the cone of positive definite quadratic forms in R''k'' and ''m'' = ''k''(''k'' + 1)/2. A Siegel domain of the second kind (or second type, or genus 2), also called a Piatetski-Shapiro domain, is the open subset of C''m''×C''n'' of elements (''z'',''w'') such that :\Im(z)-F(w,w)\in V \, where ''V'' is an open convex cone in R''m'' and ''F'' is a ''V''-valued Hermitian form on C''n''. If ''n'' = 0 this is a Siegel domain of the first kind. A Siegel domain of the third kind (or third type, or genus 3) is the open subset of C''m''×C''n''×C''k'' of elements (''z'',''w'',''t'') such that :\Im(z)-\Re L_t(w,w)\in V \, and ''t'' lies in some bounded region where ''V'' is an open convex cone in R''m'' and ''L''''t'' is a ''V''-valued semi-Hermitian form on C''n''.


Bounded homogeneous domains

A bounded domain is an open connected bounded subset of a complex affine space. It is called homogeneous if its group of automorphisms acts transitively, and is called symmetric if for every point there is an automorphism acting as –1 on the tangent space.
Bounded symmetric domain In mathematics, a Hermitian symmetric space is a Hermitian manifold which at every point has an inversion symmetry preserving the Hermitian structure. First studied by Élie Cartan, they form a natural generalization of the notion of Riemannian ...
s are homogeneous. Élie Cartan classified the homogeneous bounded domains in dimension at most 3 (up to isomorphism), showing that they are all
Hermitian symmetric space In mathematics, a Hermitian symmetric space is a Hermitian manifold which at every point has an inversion symmetry preserving the Hermitian structure. First studied by Élie Cartan, they form a natural generalization of the notion of Riemannian s ...
s. There is 1 in dimension 1 (the unit ball), two in dimension 2 (the product of two 1-dimensional complex balls or a 2-dimensional complex ball). He asked whether all bounded homogeneous domains are symmetric. answered Cartan's question by finding a Siegel domain of type 2 in 4 dimensions that is homogeneous and biholomorphic to a bounded domain but not symmetric. In dimensions at least 7 there are infinite families of homogeneous bounded domains that are not symmetric. showed that every bounded homogeneous domain is biholomorphic to a Siegel domain of type 1 or 2. described the isomorphisms of Siegel domains of types 1 and 2 and the Lie algebra of automorphisms of a Siegel domain. In particular two Siegel domains are isomorphic if and only if they are isomorphic by an affine transformation.


j-algebras

Suppose that ''G'' is the Lie algebra of a transitive connected group of analytic automorphisms of a bounded homogeneous domain ''X'', and let ''K'' be the subalgebra fixing a point ''x''. Then the almost complex structure ''j'' on ''X'' induces a vector space endomorphism ''j'' of ''G'' such that *''j''2=–1 on ''G''/''K'' * 'x'',''y''+ ''j'' 'jx'',''y''+ ''j'' 'x'',''jy'''jx'',''jy''= 0 in ''G''/''K''; this follows from the fact that the almost complex structure of ''X'' is integrable *There is a linear form ω on ''G'' such that ω 'jx'',''jy''ω 'x'',''y''and ω 'jx'',''x''0 if ''x''∉''K'' *if ''L'' is a compact subalgebra of ''G'' with ''jL''⊆''K''+''L'' then ''L''⊆''K'' A ''j''-algebra is a Lie algebra ''G'' with a subalgebra ''K'' and a linear map ''j'' satisfying the properties above. The Lie algebra of a connected Lie group acting transitively on a homogeneous bounded domain is a ''j''-algebra, which is not surprising as ''j''-algebras are defined to have the obvious properties of such a Lie algebra. The converse is also true: any ''j''-algebra is the Lie algebra of some transitive group of automorphisms of a homogeneous bounded domain. This does not give a 1:1 correspondence between homogeneous bounded domains and ''j''-algebras, because a homogeneous bounded domain can have several different Lie groups acting transitively on it.


References

* * * * * * * * * * There is an English translation in the appendix of . *{{Citation , last1=Xu , first1=Yichao , title=Theory of complex homogeneous bounded domains , url=https://books.google.com/books?id=KzqBHvRfQfYC , publisher=Science Press , location=Beijing , series=Mathematics and its Applications , isbn=978-1-4020-2132-9 , mr=2217650 , year=2005 , volume=569 Complex manifolds