Physics of optical and photoelectric phenomena in nanostructures
Course: Physics of nanosystems
Structural unit: Faculty of Physics
Title
Physics of optical and photoelectric phenomena in nanostructures
Code
ОК 6
Module type
Обов’язкова дисципліна для ОП
Educational cycle
Second
Year of study when the component is delivered
2022/2023
Semester/trimester when the component is delivered
1 Semester
Number of ECTS credits allocated
3
Learning outcomes
The learning outcomes are the ability to apply the laws of interaction of light with semiconductor nanostructures to solve practical problems.
Form of study
Full-time form
Prerequisites and co-requisites
Known the mathematical formulation and physical content of basic physical principles and laws of physics of optical and photoelectric phenomena in semiconductor nanostructures, basic theoretical and experimental approaches to consider this class of phenomena, main modern achievements of physics of optical and photoelectric phenomena in semiconductor nanostructures and their application in various fields of science and production.
Course content
The course "Physics of optical and photoelectric phenomena in nanostructures" examines modern experimental and theoretical advances in the study of optical and photoelectric phenomena in semiconductor nanostructures. The purpose of studying the discipline is to master the basic laws of absorption and scattering of light and photoelectric phenomena caused by nonequilibrium charge carriers in semiconductor nanostructures.
Recommended or required reading and other learning resources/tools
1. A.O. Podolian, O.O. Korotchenkov. Physics of low-dimensional semiconductors. Generation and recombination of nonequilibrium charge carriers. Photoelectric effect. Textbook for students of the Faculty of Physics specializations "Physics of nanosystems", "Physical materials science" and "Physics of nanostructures in metals and ceramics".-Kyiv:2018.- 63 p.
2. V.I. Boichuk, I.V. Bilynskyi, R.I. Pazyuk. Coefficient of Interband Light Absorption by InAs/GaхIn1-хAs Quantum Dot Superlattice at Low Temperatures // Physics and Chemistry of Solid State.-2017, v. 18, N2, P. 151-157.
Planned learning activities and teaching methods
Lectures - 30 hours, Self-study -60 hours, consultations.
Assessment methods and criteria
Interviews during the lecture, checking other forms of independent work. Modular tests. Final test. Two modular tests: (28-46) points. Independent work: (8-14) points. A student is not allowed to take the final test if he / she scored less than 36 points during the semester. The grade for the final test 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
Artem
Oleksandrovich
Podolyan
Department of General Physics
Faculty of Physics
Faculty of Physics
Departments
The following departments are involved in teaching the above discipline
Department of General Physics
Faculty of Physics