Physical interactions in nanosystems
Course:
Structural unit: Institute of High Technologies
Title
Physical interactions in nanosystems
Code
ОК.02
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
Knowledge and understanding of the subject area and understanding of professional activity. Ability to use the laws, theories and concepts of chemistry in conjunction with appropriate mathematical tools for describing natural phenomena. The ability to build adequate models of chemical phenomena, investigate them to obtain new conclusions and deepen the understanding of nature, including using molecular, mathematical and computer modeling methods. Ability to apply computer modeling methods to solve scientific, chemical-technological problems and problems of chemical materials science. Ability to acquire new knowledge in the field of chemistry and integrate it with existing knowledge.
Form of study
Full-time form
Prerequisites and co-requisites
1. To know the basics of solid state physics, quantum and statistical physics.
2. To be able to apply knowledge of general physics, statistical and quantum physics to the analysis of properties of physical systems and structures.
3. Have elementary skills in mathematical analysis, linear algebra, differential equations and functions of a complex variable
Course content
The main effects related to the nano-dimensionality of systems, both classical and quantum-dimensional, are considered. The main technological methods of obtaining nano-systems and the basics of modern experimental methods of controlling their morphology and physical parameters are discussed. Among the classical phenomena in nano-systems, near-field effects, elements of nano-optics and effects of modern plasmonics, which are the basis of modern nanomedicine, are considered. The properties of quantum effects in quantum wells, superlattices, quantum threads and dots are described. The features of quantum transport in quasi-one-dimensional systems are analyzed. It is shown how the studied effects can be applied in modern physics, chemistry, biology, biotechnology and medicine.
Recommended or required reading and other learning resources/tools
Main:
1. V. Mitin, V. Kochelap, M. Strasio, "Quantum Heterostructures/ Microelectronics and
Optoelectronics", Univ. Press., Cambridge, 1998
2. J. Davies, "The Physics of Low-Dimensional Semiconductors. An Introduction", Univ. Press.,
Cambridge, 1998
3. O.V. Tretyak, V.Z. Lozovskyi, "Physics of low-dimensional systems", VOC Kyiv
University, Kyiv, 2013
Additional:
1. O.V. Tretyak, V.Z. Lozovskyi, "Fundamentals of Semiconductor Physics" Volume 2, VOC
Kyiv University, Kyiv, 2009
2. O. Keller, Physics of local field // Phys. Rep.-1996.- v. 268, N2/3.
3. Girard C., Joachim C., Gauthier S. The physics of the near-field. // Rep.Prog.Phys.- 2000.-
Vol.63.- P.893-938.
4. V. Lozovski, The Effective Susceptibility Concept in the Electrodynamics of Nano-Systems
// J. Computational & Theoretical Nanosciences.- 2011.- v.7.-p.2077-2093.
Planned learning activities and teaching methods
lectures, seminar classes
Assessment methods and criteria
semester evaluation:
1. two modular test papers: RN 1.1-1.2, 4.1 - 40 points/20 points.
2. Independent semester work: RN 2.1. - 20 points/16 points
Total: 60 points/36 points.
- final assessment: exam – 40 points/24 points
Language of instruction
Ukrainian
Lecturers
This discipline is taught by the following teachers
Valery
Lozovsk
Department of Theoretical Foundations of High Technologies
Institute of High Technologies
Institute of High Technologies
Departments
The following departments are involved in teaching the above discipline
Department of Theoretical Foundations of High Technologies
Institute of High Technologies