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Gauge Theory and 4-Manifolds George D. Torres M392C - Spring 2018 1 Introduction: Classification of Manifolds 3 1.1 Dimensions 1,2, and 3 . .3 1.2 Higher Dimensions . .4 2 4-Manifold Theory I: Intersection Forms and Vector Bundles 5 2.1 Review of Cohomology and Cup Products . .5 2.2 Unimodular Forms and Signatures . .7 2.3 The intersection form and Characteristic Classes . 10 2.4 Tangent bundles of 4-manifolds . 13 2.5 Rokhlin’s Theorem . 15 3 4-Manifold Theory II: Differential Forms and Hodge Theory 18 3.1 Self-duality of 2-forms . 18 3.2 The Period Map . 23 3.3 Covariant Derivatives . 23 3.4 Gauge Transformations . 26 3.5 U(1) connections . 27 3.6 U(1) instantons . 28 4 Differential Operators and Spin Geometry 30 4.1 Clifford Algebras, Spinors, and Spin Groups . 32 4.2 Dirac Operators and the Lichnerowicz´ formula . 38 5 The Seiberg-Witten Equations 40 5.1 The Configuration Space and SW Equations . 41 5.2 Linearization . 41 5.3 Warmup on Indices of Operators . 42 5.4 Elliptic Theory and Applications to SW Compactness . 45 5.5 The Compactness Theorem . 46 5.6 Transversality . 49 5.7 The Diagonalization Theorem . 52 5.8 Seiberg Witten Invariants . 54 5.9 Symplectic 4-manifolds . 57 5.10 Applications . 61 A Appendix 64 1 ——————————————————– These are lecture notes following Tim Perutz’s Gauge Theory course M392C taught Spring 2018 at UT Austin. The reader should be comfortable with differential and algebraic topology as well as bundle theory. Homotopy theory and differential geometry won’t hurt either. Exercises are included, especially in the first few sections. Solutions to some of these exercises can be found in the Appendix. Special thanks to Riccardo Pedrotti for some of these solutions. Please send any corrections to [email protected]. Concurrent notes can be found on Tim’s web page: math.utexas.edu/users/perutz/GaugeTheory. These notes and Tim’s are meant to complement one another; Tim’s notes sometimes go into more depth on certain proofs whereas these notes offer more explanation and worked examples. ——————————————————– 2 1. Introduction: Classification of Manifolds v A more accurate title for this course is “Seiberg-Witten Theory and 4 Manifold Topology,” as the goal of this course is to understand a particular instatiation of Gauge Theory, namely Seiberg-Witten (S-W) theory in di- mension 4. Most of the results we will get to arose between the years 1994 and 2004. The essential motivation behind S-W theory comes from using partial differential equations and gauge theory to classify 4 dimensional manifolds. In this section, we will state some of the current knowledge on the general problem of classifying manifolds of a fixed dimension up to diffeomorphism. v Let M be a smooth, connected, boundary-less n manifold (assume these adjectives henceforth unless stated otherwise). We call two manifolds equivalent if they are diffeomorphic. The “ideal solution” to the classification of n manifolds up to diffeomorphism consists of answers to the following four questions for M in some class of manifolds (for example, compact manifolds): 1. What is a standard set of manifolds fXigi2I such that each manifold in te class is diffeomorphic to some Xi? The index set I need not be countable. 2. Given a description of M in some finite manner, how do we compute invariants of M to decide for which ∼ i 2 IM = Xi? A particularly nice answer would be an algorithm for doing so. 3. Given M; M 0 in our class of manifolds, how do we compute invariants of M and M 0 so that we can deter- mine if M =∼ M 0? Again, an algorithm is a good answer to this. 4. How can we understand families (fiber budles) of manifolds diffeomorphic to M. For example, what is the homotopy type of Diff(M) = fφ : M ! M smoothg? In low dimensions, we can answer all four questions in a satisfactory answer. In higher dimensions (n ≥ 4), the story is more complicated and there are certain obstructions that don’t occur in dimension 3 or less. 1.1 Dimensions 1,2, and 3 v The classification of 1 dimensional compact manifolds is trivial and is a standard exercise in introductory dif- ferential topology. As such, the above four questions have easy answers. In the case of surfaces, they also have complete answers. For example, the class of compact orientable surfaces: 1. The surfaces Σg of genus g 2 Z≥0 given by connect summing the torus g times. 2./3. These are answered by the Euler characteristic χ(S) = 2 − 2g, which is a complete invariant that is com- putable through various methods. 4. Let Diff+(S) be the group of orientation preserving self-diffeomorphisms of S and Diff+(S) be the identity component of Diff+(S). Some results due to Earle and Eels are that there are homotopy equivalences + 2 2 + 2 2 + 2 ∼ SO(3) ,! Diff (S ) and T ,! Diff (T )0, where T is the 2 torus. Moreover, π0(Diff (T )) = SL2(Z). + This covers the answer to 4) for genus 0; 1. For g > 1, Diff (Σg) is contractible (i.e. is homotpy type of + {∗}). The component group π0(Diff (Σg)) (the “mapping class group”) is infinite but finitely presented. It acts with finite stabilizers on a certain contractible manifold called Teichmuller¨ space. In dimension 3, the classification is more intricate (once again for the compact orientable class of manifolds). Thurston’s vision, which was realized by Hamilton and Perelman in recent years (see Ricci flow), led to a solution that is almost as complete as the one we have for surfaces. Moreover, the fundamental group π1(M) is very nearly a complete invariant (the main exception being with Lens spaces). 3 1 Introduction: Classification of Manifolds 1.2 Higher Dimensions v For n ≥ 4, this theory gets less optimistic. One initial warning to have is that, in general, the index set I for fXig doesn’t generally need to be countable. Thus, we can’t really hope for a list or moduli space as an answer to 1). However, it will be countable if we consider the class of compact n manifolds. If you give M an n-handlebody decomposition, you get a presentation for π1(M). If M is compact, this is a finite presentation. In fact, for n ≥ 4, all finite presentations of groups arise from n-handlebodies in this way. However, a result due to Markov says that there is no algorithm to tell if hg1; :::gk j r1; :::; r`i is a trivial group. As a result, there is no algorithm to decide whether a given n-handlebody is simply connected for n ≥ 4. Another obstruction to classification theory in these dimensions is that we can’t use powerful Riemannian metric techniques that were critical to lower dimensions. This is because for n ≥ 5, there isn’t a unique “optimal” Riemannian metric on M for Ricci flow or something equivalent for any definition of “optimal.” See [11] for a detailed discussion. In light of these obstructions, there are some revisions we have to make in order to make classification an- swerable for n ≥ 5. The first is that we restrict to considering compact, simply connected manifolds so that I is countable and there are no decidability problems with the fundamental group. In some cases, these assump- tions are good enough to answer questions 1)-3). In a wider range of cases, we have conceptual answers to these questions as well using surgery theory. In particular, surgery theory gives answers to two questions: a) Give a finite n-dimensional CW complex (n ≥ 5), when is it the homotopy type of a compact n manifold? b) Given a simply-connected compact manifold of dimension n ≥ 5, what are the diffeomorphism types of manifolds within its homotopy equivalence class? 1.2.1 Dimension 4 The focus of this class is on dimension n = 4, for which most of the above methods fail. In this case, we will still restrict to simply connected compact manifolds to avoid the obstructions mentioned above. The basic invariant of 4 dimensional Poincare´ spaces (spaces for which Poincare´ duality holds) is the intersection form 2 2 0 QP : H (P ; Z) × H (P ; Z) ! Z. This can be cast as a unimodular matrix over Z modulo a Z equivalence. This 0 0 T equivalence is Q ∼ Q if and only if Q = M QM for M 2 GLn(Z). Thus to every Poincare´ space we get a unimodular matrix (modulo a Z relation). Two important classification results related to this are: Theorem 1.1 (Milnor). The above correspondence: f4-dim s.c. compact Poincare´ spacesg=homotpy equiv. ! funimodular matrices over Zg=Z is a bijection. Theorem 1.2 (Feedman, ∼1980). There is a bijection: fCompact,simply connected topological 4-manifoldsg=homeomorphism ! funimodular matrices over Zg=Z In the smooth case, there is Rokhlin’s theorem: if X is smooth of dimension 4 and QX has even diagonal entries, then the signature of QX is divisible by 16. It is at this point that Gauge theory comes in to prove sharper and stronger results. The genesis of this was Donaldson’s diagonalizability theorem, which states that if X is compact and simply connected and if QX is positive definite, then QX ∼ I. In subsequent years, he divised invariants distinguishing infinitely many diffeomorphism types in one homotopy class. Starting in 1994 came a flood of new proofs using Seiberg-Witten theory with sharper and more general results. 0A unimodular matrix is one which is symmetric, has entries in Z, and has unit determinant 4 2.
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