- Department: Mathematics
- Credit value: 20 credits
- Credit level: M
- Academic year of delivery: 2024-25
- See module specification for other years: 2023-24
Riemannian geometry extends the study of differential geometry beyond curves and surfaces to look at geometry in any number of dimensions. The key concepts studied here are the Riemannian metric, which enables arc length to be defined and leads to the study of geodesics, and the Levi-Civita connection, which enables parallel transport and leads to the Riemannian curvature tensor.
Pre-requisite modules
Co-requisite modules
- None
Prohibited combinations
- None
While this module can be taken from a general background in pure mathematics, a first course in curves and surfaces would be an advantage.
(UG students, eg those from Natural Sciences or Physics, who have not taken Differential Geometry should consult the lecturer first if they wish to take this module).
Occurrence | Teaching period |
---|---|
A | Semester 1 2024-25 |
Riemannian geometry extends the study of differential geometry beyond curves and surfaces to look at geometry in any number of dimensions. The key concepts studied here are the Riemannian metric, which enables arc length to be defined and leads to the study of geodesics, and the Levi-Civita connection, which enables parallel transport and leads to the Riemannian curvature tensor.
By the end of the module students will be able to demonstrate understanding of, and be able to calculate with:
The concept of a manifold, including the intrinsic idea of tangent vector fields and differential 1-forms, and how these provide a framework for differential calculus.
The notion of a Riemannian metric, and how it generalises the first fundamental form of surfaces in Euclidean space.
Connections (or covariant derivatives) and parallel transport.
Riemannian curvature and related measures of curvature.
Geodesics and their relationship to length minimising curves.
The basic differential geometry of manifolds; connections, Riemannian metric and the Fundamental Theorem; Riemannian curvature and parallel transport; geodesics and the Hopf-Rinow theorem.
Task | % of module mark |
---|---|
Closed/in-person Exam (Centrally scheduled) | 100 |
None
Task | % of module mark |
---|---|
Closed/in-person Exam (Centrally scheduled) | 100 |
Current Department policy on feedback is available in the student handbook. Coursework and examinations will be marked and returned in accordance with this policy.
1. W M Boothby, An Introduction to Differentiable Manifolds and Riemannian Geometry
2 I Chavel, Riemannian geometry - a modern introduction, CUP 1995