Physics of highly excited states
Course: Physics and Astronomy
Structural unit: Faculty of Physics
Title
Physics of highly excited states
Code
ДВА. 02.10
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-03. Develop and research conceptual, mathematical and computer models of processes and systems, use them effectively to gain new knowledge and / or create innovative products in physics (astronomy) and related interdisciplinary areas.
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
Know - the main characteristics of the interaction of bombarding particles with matter, types of radiation damage, mechanisms of their migration, description of concentration profiles of point defects, effluent efficiency, their poisoning by impurity atoms, kinetics of radiation defects under different conditions, radiation-stimulated diffusion of atoms and radiation phase separation, ordering and heredity in alloys, vacancy swelling, radiation hardening, the effect of irradiation on polymers.
Be able to - creatively choose methods to describe highly excited states and radiation damage to functional materials under the action of various bombarding particles and their impact on radiation modification of physical properties, independently study and use the literature in this discipline.
Course content
The course studies: methods of obtaining excited states of matter, in particular functional materials, electronic and atomic structure of materials, the nature of the effect of excitatory radiation on crystal structures, methods of modifying functional materials using excitatory radiation.
Recommended or required reading and other learning resources/tools
1. Damascus A, Deans J. Point defects in metals. - M .: Mir, 1966, - 282 p.
2. Radiation chemistry of polymers. Edited by VA Kargina. - М .: Наука, 1973, - 454 с.
3. Vinetsky VL, Kholodar GA Radiation physics of semiconductors. - Kiev: Scientific Opinion, 1979, - 336 p.
4. Abroyan IA, Andronov AN, Titov AI Physical foundations of electronic and ionic technology. - Moscow: Higher School, 1984 - 320 p.
5. Ahiezer IA, Davydov LN Introduction to the theoretical radiation physics of metals and alloys. - Kiev: Scientific Opinion, 1985, - 144 p.
6. Ibragimov Sh.Sh., Kirsanov VV, Pyatiletov Yu.S. Radiation damage to metals and alloys. - M .: Energoatomizdat, 1985, - 140 p.
7. Phase transformations during irradiation. Ed. F.V. Noldoi. - Chelyabinsk: Metallurgy, 1989, - 312 p.
8. Jafarov TD Radiation-stimulated diffusion in semiconductors. - M .: Energoatomizdat, 1991, -288 p.
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
- semester assessment:
1. Oral examination: PH 1.1, 3.2-10 points / 5 points
2. Protection of reports of practical works: RN 2.1-2.3, 3.2 - 10 points / 5 points
5. Protection of reports of practical works 2: РН 2.1-2.3, 3.2 - 10 points / 5 points
6. Defense of the abstract: RN 1.2, 3.1 - 10 points / 5 points
- final assessment: in the form of an exam
- conditions of admission to the final exam:
Prerequisite for admission to the exam is the completion of all practical work.
Language of instruction
ukrainian
Lecturers
This discipline is taught by the following teachers
Departments
The following departments are involved in teaching the above discipline