Hopf manifold

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In complex geometry, Hopf manifold is obtained as a quotient of the complex vector space (with zero deleted) ({\Bbb C}^n\backslash 0) by a free action of the group \Gamma \cong {\Bbb Z} of integers, with the generator γ of Γ acting by holomorphic contractions. Here, a holomorphic contraction is a map \gamma:\; {\Bbb C}^n \mapsto  {\Bbb C}^n such that a sufficiently big iteration \;\gamma^N puts any given compact subset {\Bbb C}^n onto an arbitrarily small neighbourhood of 0.

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[edit] Examples

In a typical situation, Γ is generated by a linear contraction, usually a diagonal matrix q\cdot Id, with q\in {\Bbb C} a complex number, 0 < | q | < 1. Such manifold is called a classical Hopf manifold.

[edit] Properties

A Hopf manifold H:=({\Bbb C}^n\backslash 0)/{\Bbb Z} is diffeomorphic to S^{2n-1}\times S^1. It is non-Kähler. Indeed, the first cohomology group of H is odd-dimensional. By Hodge decomposition, odd cohomology of a compact Kähler manifold are always even-dimensional.

[edit] Hopf surfaces

A 2-dimensional Hopf manifold is called a Hopf surface. In the course of classification of compact complex surfaces, Kodaira classified the Hopf surfaces, by splitting them into two subclasses, called class 0 Hopf surface and class 1 Hopf surfaces. A Hopf surface is obtained as

H=\bigg({\Bbb C}^2\backslash 0\bigg)/\Gamma,

where Γ is a group generated by a polynomial contraction γ. Kodaira has found a normal form for γ. In appropriate coordinates, γ can be written as

 (x, y) \mapsto (\alpha x +\lambda y^n, \beta y)

where \alpha, \beta\in {\Bbb C} are complex numbers satisfying 0<|\alpha|\leq |\beta| <1, and either \;\lambda=0 or \;\alpha^n=\beta. When \;\lambda=0, H is called the Hopf surface of Kodaira class 1, otherwise - the Hopf surface of Kodaira class 0.

Kodaira has proven that any complex surface which is diffeomorphic to S^3\times S^1 is biholomorphic to a Hopf surface.

[edit] Hypercomplex structure

Even-dimensional Hopf manifolds admit hypercomplex structure. The Hopf surface is the only compact hypercomplex manifold of quaternionic dimension 1 which is not hyperkähler.

[edit] References

[1] K. Kodaira, On the structure of compact complex analytic surfaces, II, American J. Math., 88 (1966), 682-722.

[2] K. Kodaira, Complex structures on S^1 \times S^3, Proc. Nat. Acad. Sci. USA, 55 (1966), 240-243.