9360-0137/05 – Electronic structure modelling of solids (MES)

Gurantor department	CNT - Nanotechnology Centre	Credits	4
Subject guarantor	Ing. Dominik Legut, Ph.D.	Subject version guarantor	Ing. Dominik Legut, Ph.D.
Study level	undergraduate or graduate	Requirement	Choice-compulsory type A
Year	1	Semester	summer
		Study language	Czech
Year of introduction	2019/2020	Year of cancellation
Intended for the faculties	FMT, FEI, USP, HGF	Intended for study types	Follow-up Master

Instruction secured by
Login	Name	Tuitor	Teacher giving lectures
LEG0015	Ing. Dominik Legut, Ph.D.

Extent of instruction for forms of study
Form of study	Way of compl.	Extent
Full-time	Credit and Examination	2+2

Subject aims expressed by acquired skills and competences

Student is introduced into the field of the state of the art first principles methods to calculate electronic structure of solids, employing number of approximations as well as the to learn about the limits of the methodology. Following theoretical treatment of many physical quantities based on simple models, the practic training to obtain the same quantities from first principles calculations will be utilized.

Teaching methods

Lectures
Individual consultations
Tutorials
Project work

Summary

Compulsory literature:

Charles Kittels, Introduction to Solid State Physics, Wiley (1985). N. Ashcroft, N. Mermin, Solid State Physics, Cengage Learning (1976). R. M. Martin, Electronic Structure – Basic Theory and Practical Methods, Cambridge University Press (2004).

Recommended literature:

P. M. Chaikin, T. C. Lubensky, Principles of Condensed Matter Physics, Cambridge Press (2000). J. Singleton, Band Theory and Electronic Properties of Solids, Oxford Master Series in Physics (2001). S. Blundell, Magnetism in Condensed Matter, Oxford Master Series in Physics (2001). J. Stohr, H. C. Siegmann, Magnetism: from Fundamentals to Nanoscale Dynamics, Springer (2006). M. Fox, Quantum Optics, Oxford Master Series in Physics (2006).

Way of continuous check of knowledge in the course of semester

Written and oral form.

E-learning

Other requirements

Knowledge of unix environment, fortran or matlab-like programming is highly advantegous.

Prerequisities

Subject has no prerequisities.

Co-requisities

Subject has no co-requisities.

Subject syllabus:

THEORY 1. Introduction to electronic structure of solids 2. Symmetry of crystals and its relation to he electronic struture 3. Density functional theory - foundation of first-principles (ab initio) calculations 4. State-of-the-art methodology, approximations and limits of ab initio 5. Exchange and correlations approximaions, localization and orbial polarizatin, Hubbard model 6. Phase stability, enthalphy of formation, determination of the elastic constants, pressure induced transformations, mechanical criteria of stability 7. Phonons (lattice vibrations). Dynamical critera of crystalline stability, thermal expansion, lattice specific heat, thermodynamical quantities 8. Magnetism and electronic structure, Stoner moel, rigid band model, Heiseneberg model for magnetism, exchange and Zeeman splitting 9. Spin-orbit interaction and its effect on electronic structure, magnetism (easy and hard axis), phase stabiliy, magneto-crystalline anisotropy 10. Optical properties of solids, selection rules in dipole approximation, dielectric tensor, Kubo formula, joint density of states and Kramers-Kronig relations, magneto-optical interactions PRACTICAL sessions 11. Determination mechanical properties of transitional cubic metals, limits of elastic shear and volue moduli, Young modulus, Poisson ratio and elastic anisotropy from single elastic constants 12. Lattice vibrations (phonons) calculations for Si, phonon density of stateas and dispersion relation, determination of thermodynamical properties like lattice specific heat, entropy etc. 13. Magnetic ordering, ferro, antiferro-, ferri, etc. Decomposition of total moment into spin and orbital contributions, determination of magneto-crystalline anisotropy (effect of spin-orbit interaction) 14. Calculations of optical and magneto-optical properties, determinatin of dielectric tensor elements based on Kubo formula, absorption and dispersion in UV-VIS an X-ray energy range for 3d metals, calculations of Kerr rotation and ellipticity

Conditions for subject completion

Full-time form (validity from: 2019/2020 Winter semester)

Task name	Type of task	Max. number of points (act. for subtasks)	Min. number of points	Max. počet pokusů
Credit and Examination	Credit and Examination	100 (100)	51
Credit	Credit	40	20
Examination	Examination	60	31	3

Valid from	Valid until	Mandatory attendence participation
May 2, 2019 10:28:21 AM	Jul 12, 2019 1:52:09 PM	Successful solution of first-principles calculations of electronic structure project as well as passing the exam.

Mandatory attendence participation: Successful solution of first-principles calculations of electronic structure project.

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Conditions for subject completion and attendance at the exercises within ISP:

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Occurrence in study plans

Academic year	Programme	Zaměření	Form	Study language	Tut. centre	Year	Type of duty
2023/2024	(N0719A270002) Nanotechnology	MM2	P	Czech	Ostrava	1	Choice-compulsory type A	study plan
2022/2023	(N0719A270002) Nanotechnology	MM2	P	Czech	Ostrava	1	Choice-compulsory type A	study plan
2021/2022	(N0719A270002) Nanotechnology	MM2	P	Czech	Ostrava	1	Choice-compulsory type A	study plan
2020/2021	(N0719A270002) Nanotechnology	MM2	P	Czech	Ostrava	1	Choice-compulsory type A	study plan
2019/2020	(N0719A270002) Nanotechnology	MM2	P	Czech	Ostrava	1	Choice-compulsory type A	study plan

Occurrence in special blocks

Block name	Academic year	Form of study	Study language	Year	W	S	Type of block	Block owner

Assessment of instruction

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