|Unit level:||Level 6|
|Teaching period(s):||Semester 2|
|Offered by||School of Mathematics|
|Available as a free choice unit?:||N
Students are not permitted to take more than one of MATH31082 or MATH41082 for credit in the same or different undergraduate year. Students are not permitted to take MATH41082 and MATH61082 for credit in an undergraduate programme and then a postgraduate programme.
The course unit unit aims to introduce the basic ideas of Riemannian geometry.
Basis ideas of Riemannian geometry such as Riemannian metric, covariant differentiation, geodesics and curvature belong to the core of mathematical knowledge and are widely used in applications that range from general relativity in physics to mechanics and engineering. Besides that, this subject is one of the most beautiful in mathematics, containing such gems as Gauss's Theorema Egregium and the Gauss-Bonnet Theorem providing a link with the topology of surfaces.The course introduces these ideas, building on the course unit MATH20222 Introduction to Geometry.
On completion of this unit successful students will be able to:
- deal with various examples of Riemannian metrics;
- work practically with connection and curvature;
- appreciate the relation between geodesics and variational principle;
- apply the ideas of Riemannian geometry to other areas.
Future topics requiring this course unit
Riemannian geometry is used in almost all areas of mathematics and its applications, including physics and engineering.
Assessment Further Information
- Coursework (take-home) 20%
- End of Semester exam, 3 hours for MATH61082, 80%
RIEMANNIAN METRIC ON A DOMAIN OF Rn.
The notion of Riemannian metric in a domain of Rn.
Angle and length of tangent vetors. Arclength of a curve.
Examples of metric: sphere and other quadrics in R3; Lobachevsky plane.
Expression of metric in different coordinates.
Idea of Killing vectors.
Volume element corresponding to Riemannian metric.
Definition of a covariant derivative. Expression in local coordinates.
Examples: covariant differentiation in Rn in curvilinear coordinates.
Covariant differentiation on surfaces in Rn .
Relations between covariant differentiation and Riemannian metric. Levi-Civita connection.
GEODISICS AND PARALLEL TRANSPORT.
Idea of parallel transport. Infinitesimal parallel transport.
Equation of parallel transport. Geodesics.
Geodesics and Riemannian metric. Variational principle for geodesics.
Examples of geodesics.
THEORY OF SURFACES.
Induced Riemannian metric (First quadratic form).
Gauss-Weingarten derivation formulae.
Second quadratic form and Shape (Weingarten) operator.
Geometric meaning of Gaussian curvature and Theorema Egregium.
Infinitesimal parallel transport over a closed contour.
Definition of curvature tensor.
Gaussian curvature of surfaces and scalar curvature.
Application in Gravity theory. Einstein - Hilbert equations.
Ideas of Gauss-Bonnet theorem.
Triangulation of surfaces and Euler characteristic. Examples.
No particular textbook is followed. Students are advised to keep their own lecture notes. There are many good sources available treating various aspects of differentiable manifolds on various levels and from different viewpoints. Below is a list of texts that may be useful. More can be found by searching library shelves.
- R. Abraham, J. E. Marsden, T. Ratiu. Manifolds, tensor analysis, and applications. Springer-Verlag, 1996. ISBN 0387967907.
- B.A. Dubrovin, A.T. Fomenko, S.P. Novikov. Modern geometry, methods and applications. Part I: The Geometry of Surfaces, Transformation Groups, and Fields, Vol. 93, 1992,
- Barret O' Neill. Elementary Differential geometry, Revised Second Edition, Academic Press (Elsevier), 2006, ISBN-10: 0120887355.
Feedback tutorials will provide an opportunity for students' work to be discussed and provide feedback on their understanding. Coursework or in-class tests (where applicable) also provide an opportunity for students to receive feedback. Students can also get feedback on their understanding directly from the lecturer, for example during the lecturer's office hour.
- Lectures - 33 hours
- Tutorials - 11 hours
- Independent study hours - 106 hours