Asymptotically conical Calabi–Yau metrics on quasi-projective varieties

Conlon, Ronan J.; Hein, Hans-Joachim

doi:10.1007/s00039-015-0319-6

Cited by 28 publications

(16 citation statements)

References 54 publications

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“…In higher dimensions, by the volume non-collapsing condition we know Z is asymptotically conical. There has been extensive study on these spaces in the case when the tangent cone at infinity is smooth, see for example van Coevering [2011], Conlon and Hein [2015], C. Li [2015].…”

Section: Singularitiesmentioning

confidence: 99%

Degenerations and Moduli Spaces in Kähler Geometry

Sun¹

2019

Proceedings of the International Congress of Mathematicians (ICM 2018)

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We report some recent progress on studying degenerations and moduli spaces of canonical metrics in Kähler geometry, and the connection with algebraic geometry, with a particular emphasis on the case of Kähler-Einstein metrics. • (Yau [1978]) If = 0, then there is a unique Kähler metric ! 2 H with Ri c(!) = 0. This ! is usually referred to as a Calabi-Yau metric. • (Yau [ibid.], Aubin [1976]) If < 0 (in which case X is of general type), then there is a unique Kähler metric ! 2 H with Ri c(!) = !. • If > 0 (in which case X is a Fano manifold), then there is a Kähler metric ! 2 H with Ric(!) = ! if and only if X is K-stable. The "only if" direction is due to various authors in different generality including

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Section: Singularitiesmentioning

confidence: 99%

Degenerations and Moduli Spaces in Kähler Geometry

Sun¹

2019

Proceedings of the International Congress of Mathematicians (ICM 2018)

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“…The authors are also grateful to R. Conlon and H.-J. Hein for explaining aspects of their papers [15][16][17].…”

Section: Acknowledgementsmentioning

confidence: 99%

“…Following Yau's resolution of the Calabi Conjecture [63] the study of Ricci-flat Kähler metrics has played a central role in geometric analysis. Subsequently, motivated by questions in differential geometry, mathematical physics, and algebraic geometry there has been a great deal of interest in extensions of Yau's theorem to the complete, non-compact setting [2,3,5,11,[15][16][17][18]25,28,31,32,35,53,54,61,62], the degeneration of Calabi-Yau metrics (see, for example, the surveys [56][57][58] and the references there in), and the existence of Calabi-Yau metrics on singular spaces (see for example [24,51]). In this paper we initiate the study of degenerations of non-compact Calabi-Yau manifolds, and the existence of Calabi-Yau metrics on certain non-compact singular varieties.…”

Section: Introductionmentioning

confidence: 99%

“…The first analytic construction of asymptotically conical Calabi-Yau manifolds was given in [2,3,54], and the construction has been further refined by the work of many authors, see [15][16][17]25,28,32,35,61,62] and the references therein. One nice improvement given by these refinements is that, in analogy with Yau's theorem in the compact case [63], one is able to produce an asymptotically conical Ricci-flat Kähler metric in every suitable Kähler class on an asymptotically conical Kähler manifold X .…”

Section: Introductionmentioning

confidence: 99%

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On the degeneration of asymptotically conical Calabi–Yau metrics

2021

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We study the degenerations of asymptotically conical Ricci-flat Kähler metrics as the Kähler class degenerates to a semi-positive class. We show that under appropriate assumptions, the Ricci-flat Kähler metrics converge to a incomplete smooth Ricci-flat Kähler metric away from a compact subvariety. As a consequence, we construct singular Calabi-Yau metrics with asymptotically conical behaviour at infinity on certain quasi-projective varieties and we show that the metric geometry of these singular metrics are homeomorphic to the topology of the singular variety. Finally, we will apply our results to study several classes of examples of geometric transitions between Calabi-Yau manifolds.

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“…By our assumption Z is also endowed with a Ricci-flat Kähler metric. When Z is smooth, it is an asymptotically conical Calabi-Yau manifold, which has been well-studied recently (see for example [12]). Theorem 1.4 can also be compared with [25], where a similar result is proved for complete Kähler manifolds with non-negative bisectional curvature and maximal volume growth.…”

Section: Introductionmentioning

confidence: 99%

Gromov–Hausdorff limits of Kähler manifolds and algebraic geometry, II

Donaldson

Sun

2017

J. Differential Geom.

108

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Ric(ω) = λω for λ ∈ {1, 0, −1}; if λ = 0, we further assume K X is holomorphically trivial;(B) Uniform non-collapsing condition:Vol(B(q, r)) ≥ κr 2n(1.3) for all q ∈ X and r ∈ (0, 1].(C) Uniform volume bound: Vol(X, ω) ≤ V.(1.4)By the Bishop-Gromov volume comparison theorem, (B) and (C) together are equivalent to a uniform diameter bound on X, and the latter is indeed a consequence of the Einstein condition when λ = 1. It is proved in [16] that the (polarized) Gromov-Hausdorff limit of a sequence of spaces in K 1 (n, κ, V ) is naturally a normal projective variety. Theorem 1.1 is an extension of this result.Our main interest in this paper is on rescaled limits. For this purpose we let K(n, κ, V ) be the set of polarized Kähler manifolds of the form (X, L a , aω, p) for some (X, L, ω, p) ∈ K 1 (n, κ, V ) and a ≥ 1. Clearly K(n, κ, V ) is a subset of K(n, κ) so Theorem 1.1 applies to Gromov-Hausdorff limits of spaces in K(n, κ, V ). Let (Z, p) be such a Gromov-Hausdorff limit. We consider the family of spaces given by rescaling (Z, p) by a factor √ a for a positive integer a. Let a → ∞, by passing to a subsequence we obtain limit spaces, called the tangent cones at p. These can themselves be viewed as Gromov-Hausdorff limits of elements in K(n, κ, V ), so by Theorem 1.1 they are naturally complex analytic spaces. A fundamental result of Cheeger-Colding says that any tangent cone in this setting is also a metric cone, so is of the form C(Y ) for some compact metric space Y (called the cross section). Let R(C(Y )) denote the ring of holomorphic functions on C(Y ) with polynomial growth at infinity. Then we have 2 Complex structure on Gromov-Hausdorff limits 2.1 Proof of Theorem 1.1We first recall the notion of polarized Gromov-Hausdorff convergence introduced in [16]. Fix n and κ > 0, suppose we are given a sequence of objects (X i , L i , ω i , p i ) in K(n, κ). Then by passing to a subsequence we obtain a polarized limit space (Z, p, g ∞ , J ∞ , L ∞ , A ∞ ), which consists of the Gromov-Hausdorff limit metric space (Z, p), together with a smooth Riemannian metric g ∞ and a compatible complex structure J ∞ on the regular set R with Kähler form ω ∞ , a Hermitian line bundle L ∞ over R, and a smooth connection A ∞ on L ∞

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Asymptotically conical Calabi–Yau metrics on quasi-projective varieties

Cited by 28 publications

References 54 publications

Degenerations and Moduli Spaces in Kähler Geometry

Degenerations and Moduli Spaces in Kähler Geometry

On the degeneration of asymptotically conical Calabi–Yau metrics

Gromov–Hausdorff limits of Kähler manifolds and algebraic geometry, II

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