# Geometry in Physics

**Current updates:**

Dates of the exams:

1. Exam: Wednesday, February 7, 3-5 PM in lecture hall N5

2. Exam: Wednesday, April 11, 10-12 AM in lecture hall N14

You need to pass only one of the exams in order to obtain the credits. If you fail or miss the first one, you can take the second one. If you pass the first one, you can **not **take the second one.

Because of a public holiday, the exercise class on Wednesday, November 1, is moved to Friday, November 3, at 10.15 AM in S11. Alternatively, you may also attend the class on Thursday at 14.15 in S06.

Class begins on Mon 16 Oct 2017.

Please register here for the exercise classes.**Course Language: **

English**Studiengänge: **

This course is the module G1 of the Master in Mathematical Physics Program but is open to all degree programs.**Prerequisites: **

Math: Analysis 1 and 2 and linear algebra.

Physics: Prior knowledge is sometimes helpful but not required.**Contents:**

The course provides an introduction to fundamental methods of differential geometry and their relevance for physics. Particular topics are manifolds, differential forms, Riemannian metrics and associated notions of curvature, Riemannian geometry of submanifolds, real and complex vector bundles, and connections. Applications of these concepts in Physics are discussed. **Learning goals: **

Students obtain knowledge, understanding, and acquaintance with the use of the listed notions of differential geometry. They develop, in particular, a deeper understanding of differential and integral calculus and experience through examples how the mathematical notions are naturally applied within physical theories. **Exercises:**

The two weekly 90-minute lectures are accompanied by one weekly 90-minute exercise class, held by Felix Rexze, where the weekly homework assignments will be discussed. Participants need to register here for the exercises. If there is sufficient demand, a second exercise class will be offered.

**Literature:**

In addition to the lecture notes, the following text books could be helpful.

- John Lee, Introduction to smooth manifolds

- John Lee, Riemannian manifolds: An introduction

- Chris Isham, Modern differential geometry for physicists

- M. Nakahara, Geometry, Topology and Physics