Inoue surface

In complex geometry, an Inoue surface is any of several complex surfaces of Kodaira class VII. They are named after Masahisa Inoue, who gave the first non-trivial examples of Kodaira class VII surfaces in 1974.^[1] The Inoue surfaces are not Kähler manifolds.

Inoue surfaces with b₂ = 0

Inoue introduced three families of surfaces, S⁰, S⁺ and S⁻, which are compact quotients of [math]\displaystyle{ \Complex \times \mathbb{H} }[/math] (a product of a complex plane by a half-plane). These Inoue surfaces are solvmanifolds. They are obtained as quotients of [math]\displaystyle{ \Complex \times \mathbb{H} }[/math] by a solvable discrete group which acts holomorphically on [math]\displaystyle{ \Complex \times \mathbb{H}. }[/math]

The solvmanifold surfaces constructed by Inoue all have second Betti number [math]\displaystyle{ b_2=0 }[/math]. These surfaces are of Kodaira class VII, which means that they have [math]\displaystyle{ b_1=1 }[/math] and Kodaira dimension [math]\displaystyle{ -\infty }[/math]. It was proven by Bogomolov,^[2] Li–Yau^[3] and Teleman^[4] that any surface of class VII with [math]\displaystyle{ b_2=0 }[/math] is a Hopf surface or an Inoue-type solvmanifold.

These surfaces have no meromorphic functions and no curves.

K. Hasegawa ^[5] gives a list of all complex 2-dimensional solvmanifolds; these are complex torus, hyperelliptic surface, Kodaira surface and Inoue surfaces S⁰, S⁺ and S⁻.

The Inoue surfaces are constructed explicitly as follows.^[5]

Of type S⁰

Let φ be an integer 3 × 3 matrix, with two complex eigenvalues [math]\displaystyle{ \alpha, \overline{\alpha} }[/math] and a real eigenvalue c > 1, with [math]\displaystyle{ |\alpha|^2c=1 }[/math]. Then φ is invertible over integers, and defines an action of the group of integers, [math]\displaystyle{ \Z, }[/math] on [math]\displaystyle{ \Z^3 }[/math]. Let [math]\displaystyle{ \Gamma:=\Z^3\rtimes\Z. }[/math] This group is a lattice in solvable Lie group

[math]\displaystyle{ \R^3\rtimes\R = (\C \times\R ) \rtimes\R, }[/math]

acting on [math]\displaystyle{ \C \times \R, }[/math] with the [math]\displaystyle{ (\C \times\R ) }[/math]-part acting by translations and the [math]\displaystyle{ \rtimes\R }[/math]-part as [math]\displaystyle{ (z,r) \mapsto (\alpha^tz, c^tr). }[/math]

We extend this action to [math]\displaystyle{ \C \times \mathbb{H} = \C \times \R \times \R^{\gt 0} }[/math] by setting [math]\displaystyle{ v \mapsto e^{\log ct} v }[/math], where t is the parameter of the [math]\displaystyle{ \rtimes\R }[/math]-part of [math]\displaystyle{ \R^3\rtimes\R, }[/math] and acting trivially with the [math]\displaystyle{ \R^3 }[/math] factor on [math]\displaystyle{ \R^{\gt 0} }[/math]. This action is clearly holomorphic, and the quotient [math]\displaystyle{ \C \times \mathbb{H}/\Gamma }[/math] is called Inoue surface of type [math]\displaystyle{ S^0. }[/math]

The Inoue surface of type S⁰ is determined by the choice of an integer matrix φ, constrained as above. There is a countable number of such surfaces.

Of type S⁺

Let n be a positive integer, and [math]\displaystyle{ \Lambda_n }[/math] be the group of upper triangular matrices

[math]\displaystyle{ \begin{bmatrix} 1 & x & z/n \\ 0 & 1 & y \\ 0 & 0 & 1 \end{bmatrix}, \qquad x,y,z \in \Z. }[/math]

The quotient of [math]\displaystyle{ \Lambda_n }[/math] by its center C is [math]\displaystyle{ \Z^2 }[/math]. Let φ be an automorphism of [math]\displaystyle{ \Lambda_n }[/math], we assume that φ acts on [math]\displaystyle{ \Lambda_n/C=\Z^2 }[/math] as a matrix with two positive real eigenvalues a, b, and ab = 1. Consider the solvable group [math]\displaystyle{ \Gamma_n := \Lambda_n\rtimes \Z, }[/math] with [math]\displaystyle{ \Z }[/math] acting on [math]\displaystyle{ \Lambda_n }[/math] as φ. Identifying the group of upper triangular matrices with [math]\displaystyle{ \R^3, }[/math] we obtain an action of [math]\displaystyle{ \Gamma_n }[/math] on [math]\displaystyle{ \R^3= \C \times \R. }[/math] Define an action of [math]\displaystyle{ \Gamma_n }[/math] on [math]\displaystyle{ \C \times \mathbb{H}= \C \times \R \times \R^{\gt 0} }[/math] with [math]\displaystyle{ \Lambda_n }[/math] acting trivially on the [math]\displaystyle{ \R^{\gt 0} }[/math]-part and the [math]\displaystyle{ \Z }[/math] acting as [math]\displaystyle{ v \mapsto e^{t \log b}v. }[/math] The same argument as for Inoue surfaces of type [math]\displaystyle{ S^0 }[/math] shows that this action is holomorphic. The quotient [math]\displaystyle{ \C \times \mathbb{H}/\Gamma_n }[/math] is called Inoue surface of type [math]\displaystyle{ S^+. }[/math]

Of type S⁻

Inoue surfaces of type [math]\displaystyle{ S^- }[/math] are defined in the same way as for S⁺, but two eigenvalues a, b of φ acting on [math]\displaystyle{ \Z^2 }[/math] have opposite sign and satisfy ab = −1. Since a square of such an endomorphism defines an Inoue surface of type S⁺, an Inoue surface of type S⁻ has an unramified double cover of type S⁺.

Parabolic and hyperbolic Inoue surfaces

Parabolic and hyperbolic Inoue surfaces are Kodaira class VII surfaces defined by Iku Nakamura in 1984.^[6] They are not solvmanifolds. These surfaces have positive second Betti number. They have spherical shells, and can be deformed into a blown-up Hopf surface.

Parabolic Inoue surfaces contain a cycle of rational curves with 0 self-intersection and an elliptic curve. They are a particular case of Enoki surfaces which have a cycle of rational curves with zero self-intersection but without elliptic curve. Half-Inoue surfaces contain a cycle C of rational curves and are a quotient of a hyperbolic Inoue surface with two cycles of rational curves.

Hyperbolic Inoue surfaces are class VII₀ surfaces with two cycles of rational curves.^[7] Parabolic and hyperbolic surfaces are particular cases of minimal surfaces with global spherical shells (GSS) also called Kato surfaces. All these surfaces may be constructed by non invertible contractions.^[8]

Notes

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