TOPICS IN ADVANCED GEOMETRY
Prerequisites
Poinset topology, calculus in several real variables, some experience with the differentiable-geometric properties of regular surfaces in Euclidean 3-space.
Aims and outcomes
We shall introduce the concept of an abstract n-dimensional differentiable manifold. This is the natural space where the notion of differentiability of a map can be introduced. The tangent bundle and the subsequent theory of vector fields will be studied in detail. A large part of the course will be devoted to the construction of concrete examples of differentiable manifolds. This will be done by means of different tools ranging from the implicit function theorem up to smooth actions of discrete groups. We will see how algebraic objects such as the linear group or the orthogonal group can be endowed with a natural structure of a differentiable manifold. Meanwhile, we shall present some concepts from the theory of submanifolds and show, according to the (simplified version of a) celebrated theorem by H. Whitney, that every compact abstract manifold can be realised as a smooth subset of some Euclidean space of sufficiently high dimension.
Students are supposed to acquire the fundamental notions from the theory of abstract manifolds and submanifolds with a special attention on different techniques for the construction of concrete examples. We also expect that students acquire the basic theory of vector fields and their flows. Finally, homeworks and exercises should guide the student to develop personal abilities in the abstract investigation of basic differentiable-geometric properties of manifolds.
Program
- Differentiable structures on topological manifolds
- Smooth functions and partition of the unit
- Tangent space and differential of a smooth map
- Tangent bundle and vector fields
- Smooth coverings and smooth actions of discrete groups
- The inverse function theorem, the implicit function theorem and the rank theorem
- Immersions, regular submanifolds and embeddings
- The Whitney embedding theorem
Teaching methods
Frontal lectures. Homeworks.
Textbooks
- J. M. Lee. Introduction to Smooth Manifolds. Graduate Texts in Mathematics, 218. Springer.
- W. M. Boothby. An Introduction to Differentiable Manifolds and Riemannian Geometry. Volume 120, Pure and Applied Mathematics. Academic Press.
Final examination
Written examination based on homeworks and oral examination.
Borrowed from
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