Physical Properties of Nanosystems
Course: Physics of nanosystems
Structural unit: Faculty of Physics
Title
Physical Properties of Nanosystems
Code
ОК 10
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
2 Semester
Number of ECTS credits allocated
6
Learning outcomes
Know the theory of semiconductor nanosystems, features of calculating the density of states and concentrations of charge carriers in the low-dimensional case, the main mechanisms of charge transfer in quantum wells, wires, points and composite materials with a semiconductor componen; know the theory of high temperature stability of amorphous alloys; regularities of the phenomenon of phase stratification in amorphous alloys, properties of nanomaterials obtained by melt quenching and controlled nanostructuring from the amorphous state (controlled annealing and megaplastic deformation). Be able to study semiconductor nanosystems, logically and consistently formulate the basic laws of kinetic phenomena in them, to study the physical properties of nanomaterials obtained by quenching from melt and controlled nanostructuring from the amorphous state.
Form of study
Full-time form
Prerequisites and co-requisites
Know the basic issues of semiconductor physics, in particular: mathematical formulation and physical content of the basic concepts of semiconductor physics, its current state, the use of semiconductors in instruments and devices; laws of thermodynamics, Gibbs' method of thermodynamic potentials, thermodynamic functions of ideal and real solutions, quasi-chemical theory of solutions. Be able to work independently with the scientific literature in the field of physics of semiconductor nanosystems. To have knowledge of the basic methods of growing semiconductor materials, contact phenomena in semiconductors, skills in the application of experimental methods for studying the properties of semiconductors and computer calculation of these properties.
Course content
The course "Physical properties of nanosystems" examines both classical and modern achievements in obtaining and describing physical laws and practical use of semiconductor nanoscale systems and properties of nanomaterials obtained by melt quenching and controlled nanostructuring from the amorphous state. The aim of the discipline is to master the basic requirements for obtaining and studying low-dimensional semiconductor structures, their main types and theory of high-temperature stability of amorphous alloys, the phenomenon of phase stratification in amorphous alloys, methods and properties of nanomaterials obtained by quenching and controlled theory of high-temperature stability of amorphous alloys.
Recommended or required reading and other learning resources/tools
1. Korotchenkov O.O., Nadtochiy A.B. Introduction to the physics of low-dimensional semiconductor systems. Investigation of thermal and thermoelectric properties of thin films. Vinnytsia, Publishing House LLC "Nilan-LTD", 2021 - 76 p
2. Korotchenkov OO, Podolyan AO Physics of low-dimensional semiconductors. Generation and recombination of nonequilibrium charge carriers. Photoelectric effect. Vinnytsia, Tvory Publishing House Publishing House, 2018 - 4 prints. arch.
3. Shpak AP, Kunitsky Yu.A., Korotchenkov OO, Smyk S.Yu. Quantum low-dimensional systems. Kyiv: Akademperiodika, 2003. - 312 p.
4. Borovoy M.O., Kunitsky Yu.A., Kalenyk O.O., Ovsienko I.V., Tsaregradskaya T.L ."Nanomaterials, nanotechnologies, nanodevices". Kyiv, Interservice Publishing House, 2015, 350 p.
5. I.V. Plyushchay, T.L. Tsaregradskaya, TV Gorkavenko, О.І.Plyushchay. Collection of scientific works "Nanosystems, nanomaterials, nanotechnologies", №3 vol. 17, P.529-542, 2019
Planned learning activities and teaching methods
.Lectures - 30 hours, Laboratory work 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. Exam.
Two modular tests: (18-24) points. Self-study: (6-12) points. Protection of laboratory works (12-24 points).
A student is not allowed to take the exam if he / she scored less than 36 points during the semester.
The grade for the exam 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
Oleg
Oleksandrovich
Korotchenkov
Department of General Physics
Faculty of Physics
Faculty of Physics
Tatiana
Leonidovna
Tsaregradskaya
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
Department of General Physics
Faculty of Physics