General Physics (153 Micro- and nanosystem technology)
Type: Normative
Department: optoelectronics and information technologies
Curriculum
Semester | Credits | Reporting |
3 | 6 | Exam |
Lectures
Semester | Amount of hours | Lecturer | Group(s) |
3 | 32 | Professor Ihor Polovynko | ФеM-21 |
Laboratory works
Semester | Amount of hours | Group | Teacher(s) |
3 | 32 | ФеM-21 |
Опис навчальної дисципліни
Summary of the subject: the rearranged course is designed to familiarize students with issues related to. sources of radiant energy, Huygens’ principle, Faunhofer diffraction from a slit, light dispersion, refraction and reflection on a spherical surface, refraction of light in a thin lens, optical force, various optical devices, including a magnifying glass, microscope and telescope. Define the concepts of light polarization and optical pyrometry. Explain Rutherford’s experiments, the interaction of electrons with matter. The essence of the corpuscular-wave dualism, the origin of the radiation spectra of hydrogen atoms is explained to students. A description of the hydrogen atom in the Kantian theory, the composition of atoms, and the filling of energy levels is given. To give an understanding of the behavior of complex nuclei, the deuteron. Explain the classification of nuclear transformations.
Learning Outcomes:
To know: Structure and properties of radiation energy sources. Huygens’ principle and the Faungofer slit diffraction model. Fundamentals of light dispersion. Refraction and reflection on a spherical surface Refraction of light in a thin lens. Optical force. Polarization of light. Optical pyrometry Rutherford’s experiments Interaction of electrons with matter. The essence of the corpuscular-wave dualism, the origin of the radiation spectra of hydrogen atoms. Explanation of the properties of hydrogen atoms in the Kantian theory, properties of complex atoms. filling of energy levels. Fundamentals of the theory of complex nuclei, classification of nuclear transformations. Units used in dosimetry. Physical, chemical and biological effects of ionizing radiation
should be able to
Use radiation energy sources. Calculate diffraction and interference problems on the basis of Huygens’ principle and Faunhofer’s photomulas.
Determine the parameters of light dispersion in matter. Measure refractive and reflective indices on a spherical surface. Use the formulas for the refraction of light in a thin lens. Calculate the optical power for glasses, magnifying glasses, and other devices. Determine the properties and obtain polarized light. Work with optical pyrometers Explain Rutherford’s experiments, the interaction of electrons and nucleons with matter. Obtain and explain the emission spectra of atoms. Calculate the structure and filling of energy levels of complex atoms. Work with dosimetric devices, sources of ionizing radiation, determine their properties and radiation doses.
Recommended Literature
- G.S. Landsberg Optics. M. Soviet school Kyiv, 1961, 728 pp.
- Romaniuk M.O., Krochuk A.S. Optics, Lviv University Press.
- Kushnir O.S. Experimental optics. Lviv University Press, 2009. 115 pp.