Modern problems of physics of plasmonic nanostructures

Course: Physics and Astronomy

Structural unit: Faculty of Physics

Title
Modern problems of physics of plasmonic nanostructures
Code
ДВА. 02.22
Module type
Вибіркова дисципліна для ОП
Educational cycle
Third
Year of study when the component is delivered
2018/2019
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
1. Knowledge of methods of classical electrodynamics, optics, quantum mechanics, experimental and theoretical methods of crystal spectroscopy and molecular spectroscopy. 2. 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
Due to their unique optical properties, plasmon nanostructures currently occupy a significant niche both in basic research and in a number of applied and technological applications. The course will consider the state of modern research and applications of plasmon nanostructures in sensorics, surface amplification spectroscopy and submicron waveguide technologies.
Recommended or required reading and other learning resources/tools
1. OA Yeshchenko, "Plasmonika" // K., Phoenix, 2013, 176 p. 2. А.О. Koval, A.V. Korotun, Yu.A. Kunitsky, VA Татаренко, І.М. Titov, "Electrodynamics of plasmon effects in nanomaterials" // K., Scientific Opinion, 2021, 344 p. 3. VV Klimov, "Nanoplasmonia" // M., Fizmatlit, 2009, 480 p. 4. S. A. Maier, “Plasmonics: Fundamentals and Applications” // New York, Springer, 2007, 223 p. 5. N.L. Дмитрук, В.Г. Litovchenko, VL Strizhevsky, "Surface polaritons in semiconductors and dielectrics" // K., Naukova Dumka, 1989, 376 p. 6. E.F. Wenger, A.W. Гончаренко, М.Л. Dmytruk, "Optics of small particles and dispersed media" // K., Naukova Dumka, 1999, 348 p. 7. W. Kreibig, M. Vollmer, “Optical Properties of Metal Clusters” // Berlin, Springer, 1995, 527 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. Modular test 1 (10 points). 2. Modular test 2 (10 points). 3. Abstracts (15). 4. Poll during the lecture (10 points). 5. Independent work (15 points). - final assessment in the form of an exam: a maximum of 40 points can be obtained at the exam. - Conditions for admission to the exam: be sure to pass 2 essays on topics proposed by the teacher, get during the semester for lectures and practical classes at least 36 points.
Language of instruction
ukrainian

Lecturers

This discipline is taught by the following teachers

Oleg Anatoliiovich Yeshchenko
Department of Experimental Physics
Faculty of Physics

Departments

The following departments are involved in teaching the above discipline

Department of Experimental Physics
Faculty of Physics