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Fundamentals of dosimetry of ionizing radiation It covers the following topics: the history of dosimetry; dosimetric quantities and units of measurement; physical foundations of various methods of dosimetry of ionizing radiation; dosimetry of mixed flows of gamma and neutron radiation; dosimetry of incorporated radionuclides and aerosols; dosimetry of various types of ionizing radiation in medical physics.
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Dosimetry and radiation protection The course focuses on the study of methods of dosimetry and radiometry for applied and scientific problems in various fields of science and practice; methods of calculating the protection against ionizing radiation. Prepare for the creation of new methods of calculation of modern physical equipment, the development of methods for detecting ionizing radiation, evaluation methods of quantitative characteristics of nuclear materials.
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Instrumental methods of radiation safety The course focuses on the formation of the physical knowledge of the modern means of measuring exposure, absorbed and equivalent doses and dose rates; radiometers of neutrons, electrons, photons, alpha particles; radiometers of pulsed radiation; radiometers of aerosols and radon; types of spectrometers, gamma spectrometers; processing of gamma-ray spectra; neutron spectrometers; activation methods of neutron spectrometry.
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Quantum effects in atomic physics The aim of the course is acquaintance with quantum of photons in electromagnetics, quantum transitions in atomic physics and various types of radiation.
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Experimental methods in nuclear physics The course considers main methods to detect ionizing radiation and measure its parameters in nuclear physics experiments
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Methodology, technical implementation and data processing in a scientific experiment The course considers following issues: basic approaches to plan experimental investigation technique, random variables distribution laws, method of probability-generating function, convolution of distributions, fundamentals of measurement error theory, maximum likelihood estimation, unequal measurements, regression analysis, method of least squares, fitting criterion, correlation analysis, analysis of variance.
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Physics 1.1, 2.1, 3.1 The course is included in the basic part of the natural science and mathematics module. The course activities aims to form a fundamental knowledge base in the field of general physics.
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