Physics of nanostructures

Course: Physics of nanosystems

Structural unit: Faculty of Physics

Title
Physics of nanostructures
Code
ОК 3
Module type
Обов’язкова дисципліна для ОП
Educational cycle
Second
Year of study when the component is delivered
2023/2024
Semester/trimester when the component is delivered
1 Semester
Number of ECTS credits allocated
3
Learning outcomes
Gaining knowledge of the basic physical effects and phenomena, characteristic of systems with reduced dimensions, as well as modern methods of creating and studying nanostructures.
Form of study
Full-time form
Prerequisites and co-requisites
Knowledge gained in the course of general physics, courses in theoretical mechanics, electrodynamics, quantum mechanics, solid state physics and semiconductor physics. Knowledge of mathematical disciplines - mathematical analysis, linear algebra, theory of functions of a complex variable.
Course content
The course "Physics of Nanostructures" outlines a range of issues that form the basis of modern physical models that can be used to describe nanostructures, methods of their creation and study. The aim of the discipline is to obtain deep and systematic knowledge of nanostructure physics, which includes a range of issues that form the basis of modern physical models that can be used to describe nanostructures such as semiconductor quantum wells, quantum filaments, quantum dots, carbon nanotubes, graphene and graphene. Also to describe the main physical effects and phenomena characteristic of systems with reduced dimensions.
Recommended or required reading and other learning resources/tools
1. Charles P. Poole, Frank J. Owens. Introduction to Nanotechnology. (John Wiley & Sons 2003). 2. M. Fischetti, W.G. Vandenberghe. Advanced Physics of Electron Transport in Semiconductors and Nanostructures. (Springer International Publishing Switzerland, 2016). 3. Harald Ibach. Physics of Surfaces and Interfaces. (Springer-Verlag Berlin Heidelberg, 2006). 4. Nanotechnology and Nanoelectronics. Edd. By W. R. Fahrner. (Springer, NY, 2005). 6. Igor Tsukerman. Computational Methods for Nanoscale Applications Particles, Plasmons and Waves. Second Edition (Springer Nature Switzerland AG, 2020).
Planned learning activities and teaching methods
Lectures - 30 hours, Self-study -60 hours, consultations
Assessment methods and criteria
Interviews during the lecture, checking essays and other forms of independent work. Modular tests. Credit. Two modular tests: (15-30) points. A student is not allowed to take the credit if he / she scored less than 36 points during the semester. The grade for the credit cannot be less than 24 points to get an overall positive grade for the course.
Language of instruction
Ukrainian

Lecturers

This discipline is taught by the following teachers

Viktor Vasil'ovich Kozachenko
Department of General Physics
Faculty of Physics

Departments

The following departments are involved in teaching the above discipline

Department of General Physics
Faculty of Physics