Hyperbolic geometry and non-Kähler manifolds with trivial canonical bundle

Fine, Joël; Panov, Dmitri

doi:10.2140/gt.2010.14.1723

Cited by 48 publications

(83 citation statements)

References 42 publications

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“…Construction of non-Kähler Calabi-Yau manifolds has been studied in several recent works [Cal58,STY02,GP04,GGP08,Wu06,FP10,FLY12,FP13]. The survey by Fu [Fu10] gave an excellent introduction to this topic.…”

Section: Introductionmentioning

confidence: 99%

Non-Kähler SYZ Mirror Symmetry

Lau

Tseng

Yau

2015

Commun. Math. Phys.

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Abstract. We study SYZ mirror symmetry in the context of non-Kähler Calabi-Yau manifolds. In particular, we study the six-dimensional Type II supersymmetric SU (3) systems with Ramond-Ramond fluxes, and generalize them to higher dimensions. We show that Fourier-Mukai transform provides the mirror map between these Type IIA and Type IIB supersymmetric systems in the semi-flat setting. This is concretely exhibited by nilmanifolds.

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Section: Introductionmentioning

confidence: 99%

Non-Kähler SYZ Mirror Symmetry

Lau

Tseng

Yau

2015

Commun. Math. Phys.

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“…The corresponding question in dimensions 6, 8 and 10 is open. As was noted in [8], starting from dimension 12, symplectic twistor spaces of hyperbolic manifolds studied by Reznikov in [36] give rise to infinitely many symplectic Fano manifolds which are non-Kähler.…”

Section: Introductionmentioning

confidence: 92%

S1‐invariant symplectic hypersurfaces in dimension 6 and the Fano condition

Lindsay

Panov

2019

Journal of Topology

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We prove that any symplectic Fano 6‐manifold M with a Hamiltonian S1‐action is simply connected and satisfies c1c2false(Mfalse)=24. This is done by showing that the fixed submanifold Mtrueprefixmin⊆M on which the Hamiltonian attains its minimum is diffeomorphic to either a del Pezzo surface, a 2‐sphere or a point. In the case when dim(Mtrueprefixmin)=4, we use the fact that symplectic Fano 4‐manifolds are symplectomorphic to del Pezzo surfaces. The case when dim(Mtrueprefixmin)=2 involves a study of six‐dimensional Hamiltonian S1‐manifolds with Mmin diffeomorphic to a surface of positive genus. By exploiting an analogy with the algebro‐geometric situation we construct in each such 6‐manifold an S1‐invariant symplectic hypersurface F(M) playing the role of a smooth fibre of a hypothetical Mori fibration over Mmin. This relies upon applying Seiberg–Witten theory to the resolution of symplectic 4‐orbifolds occurring as the reduced spaces of M.

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“…From here, the main work required to prove Theorem 1 is to show that all symplectic six-dimensional orbifolds generated by Theorem 2 admit crepant symplectic resolutions (that do not change the fundamental group). A similar strategy was already applied in [7] to a particular simply connected, hyperbolic orbifold; this led to the first-known example of a simply connected, non-Kähler, symplectic Calabi-Yau. In the simply connected case of Theorem 1, where J 0 ∈ so(4) is a choice of almost complex structure on R 4 (that is, J 2 0 = −1).…”

Section: Overviewmentioning

confidence: 97%

The diversity of symplectic Calabi-Yau 6-manifolds

Fine

Panov

2013

Journal of Topology

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Given an integer b and a finitely presented group G, we produce a compact symplectic 6‐manifold with c1=0, b2>b, b3>b and π1=G. In the simply connected case, we can also arrange for b3=0; in particular, these examples are not diffeomorphic to Kähler manifolds with c1=0. The construction begins with a certain orientable, four‐dimensional, hyperbolic orbifold assembled from right‐angled 120‐cells. The twistor space of the hyperbolic orbifold is a symplectic Calabi–Yau orbifold; a crepant resolution of this last orbifold produces a smooth symplectic manifold with the required properties.

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Hyperbolic geometry and non-Kähler manifolds with trivial canonical bundle

Cited by 48 publications

References 42 publications

Non-Kähler SYZ Mirror Symmetry

Non-Kähler SYZ Mirror Symmetry

S1‐invariant symplectic hypersurfaces in dimension 6 and the Fano condition

The diversity of symplectic Calabi-Yau 6-manifolds

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