Know:
- basic concepts, phenomena and laws of plasmonics;
- regularities of interaction of electromagnetic waves of the optical range with nanoparticles of metals and their ensembles, with thin films of metals and with periodic micro and nanostructures in which metal elements are present;
- theoretical and experimental methods for studying the phenomena of plasmonics;
be able:
- be able to use professional software to solve problems of interaction of electromagnetic radiation with micro and nanostructures of radio engineering.
use theoretical research methods using computer technology to study the phenomena of plasmonics;
- apply knowledge related to plasmonics to the development of elements and designs of radio devices in which various plasmon effects are manifested.

Physics, higher mathematics, electrodynamics,
laser technologies, basics of photonics

The discipline "Plasmonika" is a special discipline that provides training for graduate students and provides the necessary knowledge for the study and study of the phenomena of plasmonics. The discipline should provide the necessary theoretical training for setting research problems of various effects of plasmonics with subsequent research and design work in accordance with the qualifications of a highly qualified specialist in the direction of 172 - Telecommunications and Radio Engineering. The purpose of teaching the discipline is to reveal modern scientific concepts, methods and tools for analyzing the interaction of electromagnetic waves in the optical range with metal nanoparticles and their ensembles, with thin films of metals and with periodic micro and nanostructures containing metal elements. This discipline is the theoretical basis of a set of knowledge and skills that form the profile of a specialist of the highest qualification in the field of telecommunications and radio engineering.

1. Климов В.В. Наноплазмоника, Москва, Физматлит, 2009, 480с
2. Стефан A. Maйєр, Плазмоніка: Теорія та застосування, R&C Dynamics, пер. з анг. 2007, Москва, 292 с.
3. Є.Ф. Венгер, А.В. Гончаренко, М.Л. Дмитрук, Оптика малих частинок і дисперсних середовищ, Наукова думка, 1999, 348 ст.
4. U. Kreibig, M. Vollmer, Optical Properties of Metal Clusters, Berlin, Springer, 1995.
5. Матвеев А.Н., Оптика: Учеб.пособие для физ.спец.вузов, М.: Высш.шк., 1993
6. Л.Д. Ландау, Е.М.Лифшиц, Электродинамика сплошных сред, Москва, Физматлит, 1986.

The knowledge of graduate students is clarified during practical classes, homework and class tests. At the end of the semester is credited.
Completion of practical work, homework and class assignments is estimated at up to 30 points. Completion of written test is estimated at up to 70 points.