Introduction to the Theory of Ferromagnetism
About this courseSkip About this course
This course focuses on the phenomenon of ferromagnetism. Ferromagnetism is a magnetically ordered state of matter in which atomic magnetic moments are parallel to each other, so that the matter has a spontaneous magnetization. Owing to ferromagnetism, some materials (such as iron) can be attracted by magnets or become the permanent magnets themselves. The phenomenon of ferromagnetism plays an important role in modern technologies. It is a physical basis for the creation of a variety of electrical and electronic devices, such as transformers, electromagnets, magnetic storage devices, hard drives, spintronic devices, etc. However, in the absence of external magnetic field ferromagnetism does not occur at any temperature. It occurs only below some critical temperature, which is called the Curie temperature. For different ferromagnetic materials, the Curie temperature has its own value. It should be noted that the phenomenon of ferromagnetism arises due to the exchange interaction, which tends to set the magnetic moments of neighboring atoms or ions parallel to each other. The exchange interaction is a purely quantum effect, which has no analogue in classical physics. In this course we shall try to understand the microscopic origin of ferromagnetism, to learn about its experimental appearing, magnetizing field, magnetic anisotropy, and quantum mechanical effect. We try to build a quantum mechanical theory of ferromagnetism. The course is aimed to graduate students wishing to improve their level in the field of theoretical physics.
At a glance
What you'll learnSkip What you'll learn
- The classification of materials by their magnetic properties
- Mean-field approach to calculation of various magnetic characteristics
- Summary of the phenomenological Landau model
- Opening lecture. Classification of phase transitions
- Atomic magnetic moment
- Physical quantities characterizing the magnetic properties of matter
- Classification of materials for their magnetic properties
- Isolated local magnetic moment in an external magnetic field
- A system of noninteracting local magnetic moments in an external magnetic field
- Curie law
- Effective Weiss field
- Exchange interaction
- Interaction of two local magnetic moments
- Heisenberg model and Ising model
- Mean-field approximation in the Ising model
- Curie-Weiss equation and Curie-Weiss law
- Ferromagnetic transition in the Ising model. Curie temperature. Order parameter
- Temperature dependence of the ferromagnetic order parameter in the Ising model
- Ground and excited states of a ferromagnet in the Ising model
- Free energy of a ferromagnet in the Ising model. Free energy of a ferromagnet near the critical temperature
- Spontaneous symmetry breaking at the paramagnetic-ferromagnetic transition
- Phenomenological Landau theory of second-order phase transitions
- Heat capacity and magnetic susceptibility of the Ising ferromagnet in the mean-field approximation
- Critical exponents
- Exact solution of the Ising model in one dimension
- Ising model for antiferromagnets. Mean-field approximation. Neél temperature
- Magnetic susceptibility of the Ising antiferromagnet in the mean-field approximation
- Problems solving. Concluding remarks
About the instructors
Frequently Asked QuestionsSkip Frequently Asked Questions
1. How difficult is the course?
The course is designed for graduate students. Thus, basic knowledge of quantum mechanics is obligatory.
2. What resources shall I need for this class?
All you need is time to study with video lectures. In addition, you will need a pen and paper to reproduce the most complex calculations made during the lectures yourself.
3. What is the main thing I shall learn if I take this course?
As a result of the course you will understand in detail the physical principles and mechanisms of the ferromagnetism phenomenon.