HYPERKÄHLER MANIFOLDS

Similar documents
Stable bundles on CP 3 and special holonomies

The Strominger Yau Zaslow conjecture

Higgs Bundles and Character Varieties

Hyperkähler geometry lecture 3

arxiv:alg-geom/ v1 29 Jul 1993

Some new torsional local models for heterotic strings

DIFFERENTIAL GEOMETRY AND THE QUATERNIONS. Nigel Hitchin (Oxford) The Chern Lectures Berkeley April 9th-18th 2013

Geometric Structures in Mathematical Physics Non-existence of almost complex structures on quaternion-kähler manifolds of positive type

Holonomy groups. Thomas Leistner. School of Mathematical Sciences Colloquium University of Adelaide, May 7, /15

Two simple ideas from calculus applied to Riemannian geometry

Moduli Space of Higgs Bundles Instructor: Marco Gualtieri

Holonomy groups. Thomas Leistner. Mathematics Colloquium School of Mathematics and Physics The University of Queensland. October 31, 2011 May 28, 2012

Mathematical Research Letters 2, (1995) A VANISHING THEOREM FOR SEIBERG-WITTEN INVARIANTS. Shuguang Wang

Linear connections on Lie groups

Marsden-Weinstein Reductions for Kähler, Hyperkähler and Quaternionic Kähler Manifolds

Twistor constructions of quaternionic manifolds and asymptotically hyperbolic Einstein Weyl spaces. Aleksandra Borówka. University of Bath

Homogeneous para-kähler Einstein manifolds. Dmitri V. Alekseevsky

INSTANTON MODULI AND COMPACTIFICATION MATTHEW MAHOWALD

An Introduction to Kuga Fiber Varieties

Constructing compact 8-manifolds with holonomy Spin(7)

As always, the story begins with Riemann surfaces or just (real) surfaces. (As we have already noted, these are nearly the same thing).

η = (e 1 (e 2 φ)) # = e 3

Algebraic geometry over quaternions

The Calabi Conjecture

Periodic monopoles and difference modules

k=0 /D : S + S /D = K 1 2 (3.5) consistently with the relation (1.75) and the Riemann-Roch-Hirzebruch-Atiyah-Singer index formula

Manifolds with holonomy. Sp(n)Sp(1) SC in SHGAP Simon Salamon Stony Brook, 9 Sep 2016

LECTURE 2: SYMPLECTIC VECTOR BUNDLES

1 Hermitian symmetric spaces: examples and basic properties

Morse theory and stable pairs

HAMILTONIAN ACTIONS IN GENERALIZED COMPLEX GEOMETRY

Holomorphic line bundles

Minimal surfaces in quaternionic symmetric spaces

K-stability and Kähler metrics, I

CALIBRATED FIBRATIONS ON NONCOMPACT MANIFOLDS VIA GROUP ACTIONS

HARMONIC MAPS INTO GRASSMANNIANS AND A GENERALIZATION OF DO CARMO-WALLACH THEOREM

Ω Ω /ω. To these, one wants to add a fourth condition that arises from physics, what is known as the anomaly cancellation, namely that

ALF spaces and collapsing Ricci-flat metrics on the K3 surface

Compact Riemannian manifolds with exceptional holonomy

EXISTENCE THEORY FOR HARMONIC METRICS

Quaternionic Complexes

SEMISIMPLE LIE GROUPS

SÉMINAIRE N. BOURBAKI

Infinitesimal Einstein Deformations. Kähler Manifolds

Mirror Symmetry: Introduction to the B Model

APPROXIMATE YANG MILLS HIGGS METRICS ON FLAT HIGGS BUNDLES OVER AN AFFINE MANIFOLD. 1. Introduction

Torus actions and Ricci-flat metrics

Uniformization in several complex variables.

12 Geometric quantization

arxiv:math/ v2 [math.ag] 1 Jul 2004

Exercises in Geometry II University of Bonn, Summer semester 2015 Professor: Prof. Christian Blohmann Assistant: Saskia Voss Sheet 1

Kähler manifolds and variations of Hodge structures

THE FOURIER TRANSFORM FOR CERTAIN HYPERKÄHLER FOURFOLDS. Contents Introduction 2

REAL INSTANTONS, DIRAC OPERATORS AND QUATERNIONIC CLASSIFYING SPACES PAUL NORBURY AND MARC SANDERS Abstract. Let M(k; SO(n)) be the moduli space of ba

Complex manifolds, Kahler metrics, differential and harmonic forms

arxiv:math/ v1 [math.ag] 18 Oct 2003

Geometric Quantization

BERGMAN KERNEL ON COMPACT KÄHLER MANIFOLDS

Moment Maps and Toric Special Holonomy

ALF spaces and collapsing Ricci-flat metrics on the K3 surface

Cohomology jump loci of local systems

The exceptional holonomy groups and calibrated geometry

SYMPLECTIC MANIFOLDS, GEOMETRIC QUANTIZATION, AND UNITARY REPRESENTATIONS OF LIE GROUPS. 1. Introduction

GEOMETRIC QUANTIZATION

Hodge Structures. October 8, A few examples of symmetric spaces

A NOTE ON RIGIDITY OF 3-SASAKIAN MANIFOLDS

Geometry of Twistor Spaces

CONFORMAL LIMITS AND THE BIA LYNICKI-BIRULA

Generalized Hitchin-Kobayashi correspondence and Weil-Petersson current

Gravitating vortices, cosmic strings, and algebraic geometry

September 27, :51 WSPC/INSTRUCTION FILE biswas-loftin. Hermitian Einstein connections on principal bundles over flat affine manifolds

arxiv: v2 [math.ag] 5 Jun 2018

Published as: J. Geom. Phys. 10 (1993)

UNIVERSAL UNFOLDINGS OF LAURENT POLYNOMIALS AND TT STRUCTURES. Claude Sabbah

Deformations of trianalytic subvarieties nal version, Oct Deformations of trianalytic subvarieties of. hyperkahler manifolds.

LAGRANGIAN HOMOLOGY CLASSES WITHOUT REGULAR MINIMIZERS

On the cohomology ring of compact hyperkähler manifolds

Survey of Taubes P SL(2, C) connections on 3-manifolds with L 2 bounds on curvature

arxiv:math/ v3 [math.dg] 5 Mar 2003

Math. Res. Lett. 13 (2006), no. 1, c International Press 2006 ENERGY IDENTITY FOR ANTI-SELF-DUAL INSTANTONS ON C Σ.

Cohomology of the Mumford Quotient

TWISTORS AND THE OCTONIONS Penrose 80. Nigel Hitchin. Oxford July 21st 2011

arxiv: v3 [hep-th] 22 Sep 2014

LECTURE 28: VECTOR BUNDLES AND FIBER BUNDLES

Metrics and Holonomy

THE NEWLANDER-NIRENBERG THEOREM. GL. The frame bundle F GL is given by x M Fx

An Invitation to Geometric Quantization

Clifford Algebras and Spin Groups

MIXED HODGE MODULES PAVEL SAFRONOV

THE MODULI SPACE OF TRANSVERSE CALABI YAU STRUCTURES ON FOLIATED MANIFOLDS

FLAT BUNDLES ON AFFINE MANIFOLDS. 1. Introduction

The Spinor Representation

Useful theorems in complex geometry

Published as: Math. Ann. 295 (1993)

H-projective structures and their applications

Topic: First Chern classes of Kähler manifolds Mitchell Faulk Last updated: April 23, 2016

On the BCOV Conjecture

THE VORTEX EQUATION ON AFFINE MANIFOLDS. 1. Introduction

Moment map flows and the Hecke correspondence for quivers

The topology of asymptotically locally flat gravitational instantons

Transcription:

HYPERKÄHLER MANIFOLDS PAVEL SAFRONOV, TALK AT 2011 TALBOT WORKSHOP 1.1. Basic definitions. 1. Hyperkähler manifolds Definition. A hyperkähler manifold is a C Riemannian manifold together with three covariantly constant orthogonal endomorphisms I, J and K of the tangent bundle which satisfy the quaternionic relations I 2 = J 2 = K 2 = IJK = 1. Note, that I, J and K give each tangent space the structure of a quaternionic vector space, so the real dimension of a hyperkähler manifold is divisible by 4. Since I, J and K are covariantly constant, a parallel transport commutes with the quaternionic multiplication and so the holonomy group is contained in O 4n GL n (H) = Sp n, the group of quaternionic unitary n n matrices. In particular, since Sp n SU 2n every hyperkähler manifold is Calabi-Yau. Examples: (1) A trivial example is H n. However, in contrast to the Kähler case, HP n is not hyperkähler and neither do its generic quaternionic submanifolds. (2) For n = 1 Sp 1 = SU2 and so every Calabi-Yau surface is hyperkähler. The only compact examples are T 4 and K3 surfaces. (3) A class of noncompact hyperkähler manifolds of real dimension 4 can be obtained by resolving the singularity of C 2 /Γ for Γ SU 2 a finite subgroup. (4) Many examples of noncompact hyperkähler manifolds arise as moduli spaces of solutions to gauge-theoretic equations. The hyperkähler structure is obtained by a hyperkähler reduction from H n. Proposition. A hyperkähler manifold M is a complex manifold with a holomorphic symplectic form. Conversely, any compact Kähler manifold with a holomorphic symplectic form is hyperkähler. Proof. Define the symplectic forms ω 1 (v, w) = g(iv, w), ω 2 (v, w) = g(jv, w) ω 3 (v, w) = g(kv, w) for v, w T M. They are of type (1, 1) in the respective complex structures. Furthermore, if we define ω + = ω 2 + iω 3, 1

2 PAVEL SAFRONOV, TALK AT 2011 TALBOT WORKSHOP it is closed, non-degenerate and covariantly constant. It is holomorphic in the complex structure I. Indeed, for any vectors v, w T C M: ω + (v, (1 + ii)w) = g(jv, (1 + ii)w) + ig(kv, (1 + ii)w) = g(jv, w) + ig(kv, w) + ig(ijv, w) g(ikv, w) = g(jv, w) + ig(kv, w) ig(kv, w) g(jv, w) = 0. Therefore, it is a holomorphic symplectic form. Conversely, suppose ω is a holomorphic symplectic form on a Kähler manifold M of real dimension 2n. Then ω n is a nowhere vanishing section of the canonical bundle which gives a holomorphic trivialization. Yau s theorem ensures the existence of a Kähler metric g with vanishing Ricci tensor. Applying Bochner s theorem one concludes that ω is covariantly constant with respect to g. Hence, the holonomy group of M is contained in Sp 2n (C) U 2n = Spn, i.e. M is hyperkähler. 1.2. Twistor space. One can attempt to encode the data of hyperkähler manifold (M, g) in a simpler complex manifold called the twistor space [Hi-92]. Observe, that for any u = (a 1, a 2, a 3 ) R 3 I 2 u = (a 1 I + a 2 J + a 3 K) 2 = (a 2 1 + a 2 2 + a 2 3). So, if u = 1, I u is an almost complex structure which is covariantly constant and therefore integrable. Define the twistor space to be a C manifold Z = M S 2. S 2 = CP 1 has a natural complex structure I 0, so there is an almost complex structure I on Z given by where (p, u) Z, v T p M and w T u S 2. Lemma. I is integrable. I p,u (v, w) = (I u v, I 0 w), Proof. The proof involves a use of Newlander-Nirenberg theorem. Remark: Newlander-Nirenberg theorem fails for Hilbert manifolds, so the integrability of the complex structure on the twistor space of a Hilbert hyperkähler manifold has to be established independently. We have the following Theorem 1. The twistor space Z of a hyperkähler manifold M is a complex manifold of dimension 2n + 1, which has the following structures: (1) A holomorphic fiber bundle p : Z CP 1. (2) Z has a real structure σ : Z Z covering the antipodal map of CP 1. (3) There is a section ϖ of 2 T Z/CP 1 p O(2) which defines a holomorphic symplectic form on each fiber and which is real with respect to σ. (4) The bundle admits a family of global holomorphic sections, whose normal bundles are all holomorphically isomorphic to C 2n C p O(1) and which are real with respect to σ. Proof. (1) The projection p : Z CP 1 defined by (m, ζ) ζ is holomorphic by the definition of the complex structure I.

HYPERKÄHLER MANIFOLDS 3 (2) The antipodal map σ : S 2 S 2 extends to an antiholmorphic involution σ : Z Z, since (I u, I 0 ) ( I u, I 0 ). (3) Recall, that ω + = ω 2 + iω 3 is holomorphic in the complex structure I. Similarly, define ϖ(ζ) = ω 2 + iω 3 + 2ζω 1 ζ 2 (ω 2 iω 3 ). ϖ(ζ) is holomorphic in the complex structure I u and defines a holomorphic symplectic form on p 1 (ζ). Globally, it can be extended into a section of 2 T Z/CP 1 p O(2). The O(2) twist is due to the quadratic dependence of ϖ(ζ) on ζ. (4) For each point m M, {m} S 2 Z is a section of Z CP 1 which is holomorphic. Its normal bundle is isomorphic to C 2n C p O(1). These sections are clearly real with respect to σ. Conversely, starting from such data we can recover the hyperkähler manifold M. Theorem 2. Suppose a complex manifold Z of dimension 2n + 1 has the structures (1)-(3) given by the previous theorem. Then the parameter space of real sections (4) is a hyperkähler manifold whose twistor space is Z. 1.3. Hyperkähler quotient. Suppose that M is a hyperkähler manifold and a compact Lie group K acts preserving the symplectic forms ω 1, ω 2, ω 3. Then we have three moment maps µ 1, µ 2, µ 3, or, equivalently, a single moment map µ : M k R 3. Denote z k the space of K-invariants. Then we have the following Theorem 3. If ζ z R 3 is a regular value, then µ 1 (ζ)/k is a hyperkähler manifold. We can characterize hyperkähler quotients in a different way. Form µ + = µ 1 +iµ 2 and then the hyperkähler quotient is the symplectic quotient of a Kähler manifold µ 1 + (α), where α z C. Finally, consider the twistor point of view. Let Z CP 1 be a twistor space for M. Then the twistor space for the hyperkähler quotient is the fiberwise symplectic quotient of Z by the holomorphic action of G. 2. Twistor space for the moduli space In this section X is a smooth projective variety over C. G will denote a connected reductive complex group and K is its maximal compact subgroup. 2.1. Quotient construction of the hyperkähler structure. The following is due to Hitchin [Hi-87] for X being a curve and Fujiki [Fu] in higher dimensions. First, fix a C principal G-bundle P X and a reduction P K X of the structure group to K. We will assume that P has a vanishing first and second Chern classes. Fix an integer k dim X + 1. Define the group of complex gauge transformations to be G = Γ(X, Ad P ), where the sections are of class H k+1, it is naturally a Hilbert Lie group. Similarly, there is a group of real gauge transformations K = Γ(X, Ad P K ). We have a decomposition ad P = ad P K i ad P K, which

4 PAVEL SAFRONOV, TALK AT 2011 TALBOT WORKSHOP gives ad P a complex structure. The space of all connections on P (P K ) of class H k will be denoted by A (A K ). Lemma. A is a Hilbert hyperkähler manifold. Proof. First consider A K. Its tangent space is identified with Ω 1 R (X; ad P K). Then we have a natural complex structure I on Ω 1 (X) coming from the complex structure on X. A compatible metric on A K is given by (α, β) A = (α, β) X ω n, X where (, ) X is a combination of the inner product on T X given by the Kähler metric on X, and an inner product on ad P. This is an H 0 metric, a metric for higher k has a similar form. The tangent space to A at each point is Ω 1 C (X; ad P ) and is naturally a complexification of Ω 1 R (X; ad P K). Denote the corresponding complex structure as J. If we extend I antilinearly, then IJ = JI and so A is a hyperkähler manifold. Denote the J-holomorphic symplectic form as ω + = α β ω n 1 X. X G acts holomorphically on (A, J) preserving the hyperkähler metric. This action extends to a fiberwise holomorphic action on the associated twistor space Z A. It preserves the holomorphic sympelctic form and the associated moment map is µ + (d) = iλf d, where Λ is the Lefschetz operator adjoint to a multiplication by ω X. Similarly, K acts on (A, I) preserving the Kähler form. Recall, that d can be decomposed as d = d + + θ, where d + is a connection along P K and θ is orthogonal to P K, i.e. θ Ω 1 (i ad P K ). We can decompose d + and θ further according to type: We will also form d + = d + d, θ = θ + θ. = d + θ, = d + θ. Then a result of Corlette says that the moment map is given by µ 3 = id +, θ. Denote T the resulting hyperkähler quotient of A by G. It is a moduli space of irreducible Einstein weakly harmonic connections (i.e. such that d +, θ = 0). In general this is an infinitedimensional space and we want to reduce it further to obtain a finite-dimensional subspace. There are two natural choices:

HYPERKÄHLER MANIFOLDS 5 (1) Denote T J T the subset of all connections d such that the curvature F d is of type (1, 1). By using the complex structure on ad P and the type decomposition of the forms we conclude that 0 = F 2,0 d + + [θ, θ ] = d θ 0 = F 0,2 d + + [θ, θ ] = d θ Then (P, ) and (P, ) are antiholomorphic and holomorphic bundles respectively. Summarizing, T J parametrizes principal bundles (P, d) with an irreducible, Einstein, weakly harmonic connection d, such that its curvature is of type (1, 1). (2) We can also consider a subset T I T of all connections d, such that the curvature F d + is of type (1, 1), θ is holomorphic with respect to d + θ and [θ θ] = 0. Clearly, T I is the moduli space of stable G-Higgs bundles. Recall a theorem of Simpson: Theorem 4. Let (P, d) be a connected principal bundle whose curvature is of type (1, 1) and Einstein. Then the metric P K is harmonic iff the Higgs field is integrable: [θ θ ] = 0. Any stable G-Higgs bundle admits an irreducible Hermitian-Einstein metric and, since the first and second Chern classes vanish, we have an identification of sets T I = TJ, where T J is a subset of T J consisting of harmonic bundles with a flat metric. 2.2. Harmonic bundles and λ-connections. Consider a flat G-bundle P X with a harmonic metric. Decompose d as before and for any λ C define λ = + λθ, λ = λ + θ. Lemma. (P, λ, λ ) is a holomorphic G-bundle with a flat λ-connection. We get a natural identification T J = MHod (X, G) λ. 2.3. Deligne moduli space. Fix a basepoint x X. Recall, that the Hodge moduli space R Hod (X, x, G) A 1 parametrizes principal G-bundles on X with integrable λ-connections and a frame at x. M Hod (X, G) is the GIT quotient of R Hod (X, x, G) by G acting by a change of frame. The fiber at 0 is identified with M Dol (X, G) and the fiber at 1 is identified with M DR (X, G). The action of G m on A 1 lifts to R Hod (X, xi, G) which then descends to M Hod (X, G) and allows one to identify the fibers at all λ 0 with M DR (X, G). The map τ : M B (X, G) (an) M B (X, G) (an) that sends a representation ρ to the dual of its complex conjugate is an antilinear involution. Using the Riemann-Hilbert correspondence M B (X, G) (an) = MDR (X, G) an it lifts to an antilinear involution on M DR (X, G) an. Define an antilinear involution by σ : M DR (X, G) an G m M DR (X, G) an G m σ (ρ, λ) = (τ(ρ), λ 1 ).

6 PAVEL SAFRONOV, TALK AT 2011 TALBOT WORKSHOP The antilinear involution allows one to identify M Hod (X, G) with M Hod (X, G) over G m : M DR (X, G) an G m = MDR (X, G) an G m = MDR (X, G) an G m, where the first map is σ. Using this identification we may define the Deligne moduli space M Del (X, G) = M Hod (X, G) G m M Hod (X, G). The construction is due to Deligne and Simpson [Si]. Theorem 5. M Del (X, G) is a twistor space in the sense of theorem 1. Proof. (1) Define p : M Del (X, G) P 1 as M Hod (X, G) A 1, where A 1 is the patch with the local coordinate λ and M Hod (X, G) A 1, where A 1 is the patch with the local coordinate 1/λ. These maps agree on the intersection. (2) The real structure σ is given by σ over G m and the canonical antilinear isomorphism M Dol (X, G) an = MDol (X, G) an over 0 and. (3) The symplectic structure is the same as in Fujiki s construction. (4) Real sections are given by harmonic bundles as before. If we denote the space of real sections as M, we see that M Del (X, G) = M CP 1 as C manifolds, so we have M Dol (X, G) = M = M DR (X, G). References [Fu] A. Fujiki Hyperkähler structure on the moduli space of flat bundles, Prospects in Complex Geometry, L.N.M. 1468 (1991), 1-83. [HKLR] N. Hitchin, A. Karlhede, U. Lindstrøm and M. Ro cek Hyperkähler metrics and supersymmetry, Commun. Math. Phys. 108 (1987), 535-559. [Hi-87] N. Hitchin The self-duality equations on a Riemann surface, Proc. London Math. Soc. (3) 55 (1987), 59-126. [Hi-92] N. Hitchin Hyperkähler manifolds, Séminaire Bourbaki, exp. n 748, Astérisque, t. 206 (1992), 137-166. [Si] C. Simpson The Hodge filtration on nonabelian cohomology. Algebraic geometry Santa Cruz 1995, Proc. Sympos. Pure Math., 62, Part 2, A.M.S. (1997), 217-281.

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback