# General physics: electromagnetism

## Summary

The topics covered by the course are concepts of fluid mechanics, waves, and electromagnetism.

## Content

**Concepts of fluid mechanics**

- Statics and dynamics of ideal fluids**Waves**

- General understanding of wave motion, including energetic aspects

- Description of different waves propagating in a dense medium

- Electromagnetic waves, Poynting vector, energy considerations

- Superposition of waves: reflection, stationary waves via interference**Electromagnetism**

- Electrostatics: Coulomb law and electric field, Gauss law, electric potential, capacity and energy, electric fields in dielectric matter

- Electrical currents and AC circuits

- Magnetostatics: electric current and magnetic field, the two fundamental laws, magnetic properties of matter, ferromagnetism.

- The Faraday law: the electromotive force, the law of induction, self and mutual inductances, the magnetic energy

- Maxwell equations: the displacement current and Maxwell equations in vacuum and materials

## Keywords

Electromagnetism, electricity and magnetism, interference, Poynting vector, Maxwell's equations, vector calculus, div, grad, curl, Laplacian (in different coordinate systems), vector and integral identities

## Learning Prerequisites

## Required courses

General Physics I, II

## Recommended courses

Mathematics courses 1st year

## Learning Outcomes

By the end of the course, the student must be able to:

- Integrate topics of the course
- Manipulate equations given in the course
- Apply concepts given in the course to practical problems
- Solve problems using the concepts given in the course
- Choose appropriate method for solving a problem
- Deduce properties on the basis of fundamental laws
- Analyze quantitatively consequences of a charge moving in a magnetic field, radiation of an electromagnetic wave from an antenna, reflection of photons at a metal surface, etc.

## Transversal skills

- Use a work methodology appropriate to the task.
- Communicate effectively, being understood, including across different languages and cultures.
- Give feedback (critique) in an appropriate fashion.

## Teaching methods

Ex cathedra with demonstrations and exercises in class; clickers

## Expected student activities

Attendance at lectures and exercise classes, completing exercises, revision of lecture contents by consulting relevant books, feedback (also via e.g. electronic means (clickers))

## Assessment methods

Written Exam

## Supervision

Office hours | Yes |

Assistants | Yes |

## Resources

## Bibliography

There are several textbooks that address concepts and aspects of the lecture (on different levels). Among them there are the following: (in French or English) M. Alonso and E.J. Finn: "Physique generale - 2. Champs et ondes", 2. Ed. - Dunod (Paris); F. A. Reuse, "Electrodynamique", PPUR; (in English) A. Zangwill, "Modern Electrodynamics", Cambridge University Press; (advanced level) J. D. Jackson, "Classical Electrodynamics, 3rd Edition, Wiley. Introduction to electrodynamics, David J. Griffiths, 2014. Fluid mechanics - fundamentals and applications, Yunus A.Çengel, John M. Cimbala, 2010. Further textbooks are available in the library.

## Websites

## Moodle Link

## Prerequisite for

General physics IV and Electromagnetism II

## In the programs

**Semester:**Fall**Exam form:**Written (winter session)**Subject examined:**General physics: electromagnetism**Lecture:**4 Hour(s) per week x 14 weeks**Exercises:**2 Hour(s) per week x 14 weeks

**Semester:**Fall**Exam form:**Written (winter session)**Subject examined:**General physics: electromagnetism**Lecture:**4 Hour(s) per week x 14 weeks**Exercises:**2 Hour(s) per week x 14 weeks

**Semester:**Fall**Exam form:**Written (winter session)**Subject examined:**General physics: electromagnetism**Lecture:**4 Hour(s) per week x 14 weeks**Exercises:**2 Hour(s) per week x 14 weeks