Physical properties of low-dimensional systems
Course: Physics and Astronomy
Structural unit: Faculty of Physics
Title
Physical properties of low-dimensional systems
Code
ДВА. 02.08
Module type
Вибіркова дисципліна для ОП
Educational cycle
Third
Year of study when the component is delivered
2023/2024
Semester/trimester when the component is delivered
4 Semester
Number of ECTS credits allocated
4
Learning outcomes
PLO-04. Plan and perform experimental and / or theoretical research in physics (astronomy) and related interdisciplinary fields using modern tools, critically analyze the results of their own research and the results of other researchers in the context of the whole complex of modern knowledge on the research problem.
PLO-07. Deeply understand the general principles and methods of natural sciences, as well as the methodology of scientific research, be able to apply them in their own research in physics (astronomy) and in teaching practice.
Form of study
Distance form
Prerequisites and co-requisites
- knowledge of methods of classical electrodynamics, optics, quantum mechanics, experimental and theoretical methods of crystal spectroscopy and molecular spectroscopy;
- ability to quantitatively analyze and interpret spectral information obtained from the spectra of absorption, scattering and photoluminescence, to draw conclusions about the dominant physical mechanisms that determine the optical spectra of the studied systems; use theoretical analytical methods and computer modeling methods to calculate the electronic optical spectra of nanostructures.
Course content
The discipline belongs to the list of disciplines of free choice of graduate student. Due to their unique physical properties, nanoscale structures currently occupy a significant niche both in basic research and in a number of applied and technological applications. The course will consider the physical principles of analysis of the properties of low-dimensional systems and the state of modern research and applications of nanostructures in electronics, photonics, laser technology.
Recommended or required reading and other learning resources/tools
1. І.М. Dmitruk. Electronic processes in nanostructures. Kyiv, 2013, 144 pages.
2. IM Dmitruk, OA Yeshchenko SPECTROSCOPY OF CRYSTALS (lecture notes) Textbook for students of the Faculty of Physics Kyiv - 2006. 147 p.
Additionally:
1. VV Klimov, "Nanoplasmonia" // M., Fizmatlit, 2009, 480 p.
2. Landau, Lifshitz, “Quantum mechanics. Nonrelativistic theory.
3. T.P. Martin “Shells of atoms”, Physics Reports, 273, 1996, 199-241.
4. A.I. Ekimov, A.L. Efros, A.A. Onushchenko, “Quantum size effect in semiconductor microcrystals”, Solid State Communications, 56 (1985), 921-924.
Planned learning activities and teaching methods
The total amount of 120 hours, including:
lectures - 18 hours;
practical classes - 4 hours;
consultations - 2 hours;
independent work - 96 hours.
Assessment methods and criteria
Assessment methods: interviews during lectures, tests after the main sections of the course, exam. The final grade is set on the basis of intermediate grades (60%) and the exam (40%).
Language of instruction
ukrainian
Lecturers
This discipline is taught by the following teachers
Departments
The following departments are involved in teaching the above discipline