Infopaket

Physics of Optotechnique Materials

ДВА. 02.03

Вибіркова дисципліна для ОП

Third

2018/2019

4 Semester

4

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.

Distance form

1. Know the basic principles of solid state theory, approaches to describing the behavior of electronic and ionic (atomic) subsystems of condensed media and features of their response to excitation by electromagnetic waves, calculation of energy spectra of density of electronic states for both ordered and disordered systems. 2. Be able to propose experimental methods for determining the optical and electronic characteristics of both continuous and nanostructured media used in devices of optoelectronics, laser technology and information networks. 3. Have the skills to perform optical polarization measurements for inhomogeneous surface layers of media with different conductivities, finding angular, azimuthal and spectral ellipsometric characteristics and calculation of thicknesses and optical stable semiconductor heterostructures and thin films on metal surfaces

The discipline includes the study of sections: basic physical processes that accompany the interaction of light with various materials from transparent to highly absorbing, taking into account losses due to absorbing and scattering components when passing through thin transitional and reflective surface layers of media with different conductivity, optical properties and optical properties. structure of semiconductor single crystals, noncrystalline dielectric materials, amorphous metal alloys, nanocrystalline solids, development of new goniopolarimetry methods and algorithms for processing experimental optical data.

1. Emil Wolf. Introduction to the Theory of Coherence and Polarization of Light / Emil Wolf. - New York: United States of America by Cambridge University Press, 2007. 2. Max Born, Emil Wolf. Principles of Optics. Electromagnetic theory of propagation, interference and diffraction of light. / Max Born, Emil Wolf. - New York: United States of America by Cambridge University Press, 1999. 3. B.E.A. Salen, M.C. Teich. Fundamentals of Photonics / Salen B.E.A., Teich M.C. - USA: John Wiley & Sons, Inc, 1991. 4. William T. Silfvast. Laser Fundamentals / William T. Silfvast. - New York: Cambridge University Press, 1996. 5. Zaiman J. Calculation of Bloch functions / J. Zaiman. - Moscow: Mir, 1973. 6. Harald Ibach, Hans Luth. Solid-state physics. An Introduction to Theory and Experiment / Harald Ibach, Hans Luth. - Berlin: Springer-Verlag, 1990. 7. Hans Luth. Surfaces and Interfaces of Solids / Hans Luth. - Berlin: Springer-Verlag, 1993.

The total amount of 120 hours, including: lectures - 18 hours; practical classes - 4 hours; consultations - 2 hours; independent work - 96 hours.

Forms of postgraduate evaluation: - semester assessment: 1. Modular test 1: 25 points 2. Modular test 2: 25 points - final assessment in the form of an exam: - 50 points - conditions of admission to the final test: A graduate student is not admitted to the exam if he / she scored less than 20 points during the semester

ukrainian