Magistracy
Speciality Code:
7M05308
Speciality Name:
Physics
Faculty:
of Physics and Technology
 Model of graduating student
 Mandatory disciplines
 Elective disciplines
 Professional
Upon completion of this educational program, it is expected that undergraduates will be able to:
1. ON1 – to set, to obtain data with an estimate of measurement errors and interpret the results of the experiment in the fields of theoretical physics, thermal physics, plasma physics and medical physics;
2. ON2 – to explain the experimental data obtained using modern theories and the involvement of physical models, phenomena and processes;
3. ON3 freely operate with computer programs, mathematical and numerical methods for the compilation of models and calculations of phenomena and processes in the fields of theoretical physics, thermal physics, plasma physics and medical physics;
4. ON4 to build graphs, dependencies of various parameters of physical systems;
5. ON5 to critical to evaluate the results of calculations, research and experiments, to make a report on the work performed;
6. ON6  to substantiate the scientific results on a specific physical problem in order to achieve joint goals and accomplish tasks;
7. ON7  effectively demonstrate the skills and express in the most digestible form of their knowledge to the audience;
8. ON8to use modern educational technology and take into account the psychological and age characteristics of the audience when presenting materials;
9. ON9to evaluate learning outcomes using modern technologies;
10. ON10 to organize and motivate students to obtain optimal learning outcomes;
11. ON11 to use distance learning technologies with the use of innovative techniques.
ON12to understand the nature and social significance of their future profession, to show a steady interest in it, to achieve the proper level of physical fitness necessary for the development of professional skills in the process of learning in the university.
1. ON1 – to set, to obtain data with an estimate of measurement errors and interpret the results of the experiment in the fields of theoretical physics, thermal physics, plasma physics and medical physics;
2. ON2 – to explain the experimental data obtained using modern theories and the involvement of physical models, phenomena and processes;
3. ON3 freely operate with computer programs, mathematical and numerical methods for the compilation of models and calculations of phenomena and processes in the fields of theoretical physics, thermal physics, plasma physics and medical physics;
4. ON4 to build graphs, dependencies of various parameters of physical systems;
5. ON5 to critical to evaluate the results of calculations, research and experiments, to make a report on the work performed;
6. ON6  to substantiate the scientific results on a specific physical problem in order to achieve joint goals and accomplish tasks;
7. ON7  effectively demonstrate the skills and express in the most digestible form of their knowledge to the audience;
8. ON8to use modern educational technology and take into account the psychological and age characteristics of the audience when presenting materials;
9. ON9to evaluate learning outcomes using modern technologies;
10. ON10 to organize and motivate students to obtain optimal learning outcomes;
11. ON11 to use distance learning technologies with the use of innovative techniques.
ON12to understand the nature and social significance of their future profession, to show a steady interest in it, to achieve the proper level of physical fitness necessary for the development of professional skills in the process of learning in the university.

Nuclear Astrophysics
 Number of credits: 5
 Type of control: [RK1+MT1+RK2+Exam] (100)
 Description: The purpose of studying of discipline is to form students' knowledge of the modern problem of astrophysics and nuclear reactions in stellar matter. During the study of course, master students should be competent in: 1. to formulate the laws of physics apply to space objects; 2. analyze scientific and technical information, 3. to study domestic and foreign experience in the field of research; 4. to use fundamental knowledge in the field of modern nuclear astrophysics; 5. use physical methods for space objects. Abstract оf discipline: Stars and interstellar medium. The birth of stars. Galaxies and quasars. The application of physical laws to the study of cosmic objects (stars, cosmic plasma) and the universe as a whole. Sources of stellar energy. Equations of radiation transfer and their simplest solutions. Nuclear reactions in stars and other astronomical objects. Energy and nuclear fission mechanisms. The luminosity of stars and their mass. Physical methods of research of space objects. Nuclear reactions in astrophysical objects. Modern problems of astrophysics. To study the basic concepts of astrophysics, the laws of the world of stars and modern theoretical concepts about the nature of stars and their systems; to show the effect of fundamental laws in space conditions; to study physical methods of space objects research; to get acquainted with modern problems of astrophysics, the latest discoveries and achievements in the study of the universe in recent years.

Master’s dissertation preparation and defense (MDPaD)
 Number of credits: 12
 Type of control: Master Dissertation
 Description: The main purpose of "The implementation of a Master Thesis": the formation of master students in preparation for the defense of the thesis for the Master in specialty (by industry). During the study of course, master student's should be competent in: 1. demonstrate the progress of solving problems arising in the course of research activities and requiring indepth professional knowledge; 2. to argue for carrying out theoretical or experimental research within the framework of the tasks, including a mathematical (simulation) experiment; 3. can choose the necessary research methods, modify existing methods and develop new methods, based on the tasks of the specific study; 4. to use foreign languages for independent work on normative sources and scientific literature; 5. formulate the goals and objectives of the dissertation research, determine the scientific novelty and practical significance of the results of research activities; to develop a structurally methodological scheme for performing research.

Introduction to the Quantum Theory of a Field
 Number of credits: 5
 Type of control: [RK1+MT1+RK2+Exam] (100)
 Description: The purpose of the discipline is study of the basic concepts of quantum field theory and symmetry relations of physical systems with respect to various transformations of spacetime coordinates with conservation laws During the study of course, master students should be competent in: 1. own methods of quantum field theory; 2. calculate the conversion rate in modern physical calculations; 3. apply the uncertainty principle to explain the features of the microworld; 4. use the relativistic invariant when describing processes at high energies in the microworld; 5. explain the relationship of the laws of conservation of physical quantities with the properties of the symmetry of spacetime. Abstract оf discipline: Relativity principle. Galileo and Lorenz transformations. Equation of physics in invariant form. Correspondence principle as a guide at construction of new physical theories. Conserving quantities in quantum physics. Operator of symmetry and unitary transformations. Conception about virtual particles and processes. A consideration of additive and multiplicative laws of conservation because of the characters of transformation generators remaining the system to be invariant; a consideration of principles of physics (relativity, symmetry, superposition, uncertainty, correspondence).

Computer Modeling of Multipartial Systems
 Number of credits: 5
 Type of control: [RK1+MT1+RK2+Exam] (100)
 Description: The purpose of studying of the discipline is to form master students' ideas about the methods, goals and objectives of computer simulation of manyparticle systems; to acquaint master students with modern methods of computer modeling of classical and quantum multiparticle systems, the ability to calculate the physical properties and characteristics of multiparticle systems; During the study of course, master students should be competent in: 1. understand basics of numerical methods used for investigation properties of manyparticle system 2. use basic numerical methods for investigation processes in manyparticle system; 3. development of the computer software programs for studying manyparticle system and its application in this course 4. has conception about main phenomena in manyparticle system and investigation methods and applicability boundaries; 5. has skills of working with literature on subject; 6. has knowledge of numerical solution describing processes in manyparticle system During the study of the discipline students will learn following aspects: Theoretical methods for analyzing and solving nonlinear, differential, integral equations that describe various processes in a plasma. Creation of models of physical objects, phenomena, processes in plasma. Monte Carlo methods, molecular dynamics and quasiparticles. Implement these methods on specific tasks. To get know students with basic numerical methods of mathematical simulation of processes in plasma, advantages and disadvantages of each one, compare and show applicability of numerical methods, to train skills of using numerical methods for solving tasks in plasma physics.

Basic Principles of Modern Physics
 Number of credits: 5
 Type of control: [RK1+MT1+RK2+Exam] (100)
 Description: The purpose of studying of discipline: familiarization with the basic concepts, laws, theories of classical and modern physics in their internal relationship and integrity. During the study of course, masters should be competent in: 1. classify existing approaches to the study of modern problems of physics; 2. determine the fundamental physical laws of spatial development and identify causeeffect relationships for modern physical processes; 3. characterize the modern field of physics, its current state and development prospects; 4. use physical knowledge through new information and communication technologies in applied research; 5. effectively apply the basic methods, laws and principles in the construction, solutions and analysis of the studied problems in technical physics.

Foreign Language (professional)
 Number of credits: 5
 Type of control: [RK1+MT1+RK2+Exam] (100)
 Description: The purpose of the discipline: the acquisition and improvement of competencies in accordance with international standards of foreign language education, allowing the use of a foreign language as a means of communication for the successful professional and scientific activities of the future master. able to compete in the labor market, as new knowledge, technologies are available through a foreign language, mastering a professional foreign language serves as a tool in mastering new competencies

History and philosophy of science
 Number of credits: 3
 Type of control: [RK1+MT1+RK2+Exam] (100)
 Description: The course "History and Philosophy of Science" introduces the problem of science as an object of special philosophical analysis, forms knowledge about the history and theory of science; on the laws of the development of science and the structure of scientific knowledge; about science as a profession and social institution; оn the methods of conducting scientific research; the role of science in the development of society. The maintenance of a course includes detection of specifics and interrelation of the main problems, subjects of philosophy of science and history of science; studying consciousness of science in its social and philosophical foreshortenings; consideration of a phenomenon of science as professions, social institute and direct productive force; disclosure of disciplinary selfdetermination of natural, social and technical science, their communities and distinction.

Organization and planning of scientific research
 Number of credits: 5
 Type of control: [RK1+MT1+RK2+Exam] (100)
 Description: Purpose of discipline: During the study of course, students should be competent in:  show methods of setting goals and objectives of scientific and project research;  to carry out methods of experimental research, processing and analysis of the results;  to systematize domestic and foreign experience in the direction of research in the field of machinebuilding production, to set goals and define tasks in the organization, to plan scientific and project research;  analyze modern scientific and technical information, organize and conduct experimental research in the field of oil and gas industry (on the topic of master's thesis), presentation of the results of scientific research and conducting scientific discussions. During the study of the discipline students will learn following aspects: The discipline is aimed at studying the basics of scientific method, methodology of literary and experimental research, rules of preparation and review of scientific publications and projects. Special attention will be paid to the search and analysis of scientific literature, selection of research topic, planning of experiments, performance and commercialization of research results, the preparation and submission of research projects, the requirements for academic degrees and titles, the evaluation of the effectiveness of the work of scientists and the norms of scientific ethics.

Pedagogy of higher education
 Number of credits: 5
 Type of control: [RK1+MT1+RK2+Exam] (100)
 Description: In the study of the discipline will be considered the following topics: scientifically based understanding of the system of psychological variables of behavior and conscious human activity in scientific and pedagogical activities necessary to solve personal and professional problems.

Psychology of management
 Number of credits: 3
 Type of control: [RK1+MT1+RK2+Exam] (100)
 Description: The purpose of the discipline is to provide scientific training for highly qualified specialists on the basis of studying the fundamental concepts of management psychology, capable of understanding the current state of the theory and practice of management psychology in an amount optimal for use in subsequent professional activities; apply and describe psychological methods of studying individuals and social groups (communities) in order to increase management efficiency;

Super simmetry in the theory of elementary particles
 Type of control: [RK1+MT1+RK2+Exam] (100)
 Description: The purpose of studying of discipline – provide master students with an introduction to the subject of supersymmetry, introduce them to physics based on the idea of symmetry between bosons and fermions; During the study of course, master students should be competent in: 1. formulate the basics of modern relativistic astrophysics; 2. solve independently applied and theoretical problems; 3. own: skills in the formulation and solution of problems on a given topic. 4. use the current knowledge of the largescale structure and evolution of the universe 5. demonstrate a thorough understanding of the laws of the macrouniverse. The latest discoveries in astrophysics associated with the detection of exotic compact objects, dark matter and dark energy. The purpose of the course is. The subject and objects of study of relativistic astrophysics. Recent discoveries in astrophysics. The physical structure of the universe. The theory of the expanding universe. Modern problems of cosmology. To study methods of theoretical investigation of structure and evolution of the Universe.

Introduction to quantum chromodynamics
 Type of control: [RK1+MT1+RK2+Exam] (100)
 Description: The purpose of studying of discipline – provide masters students with an introduction to the subject of Quantum Chromodynamics, introduce with physics of gluons and quarks and also modern methods of theories of strong interaction. During the study of course, master students should be competent in: 1. to expand the horizons in physical theories; 2. to examine methods on quarks and gluons; 3. to formulate problems of quantum chromodynamics; 4. to use ways of its solution; 5. to interpret classification of elementary particles in quantum chromodynamics. Abstract оf discipline: Perturbative methods in quantum chromodynamics. Divergence in the quantum theory of the field and methods of their elimination. A method of renormalizatsionny group in quantum chromodynamics. An invariant charge and asymptotic freedom in quantum chromodynamics. Partonny model. The description of processes of strong interaction in the timelike area.

Gas discharges in dense and rare gases
 Type of control: [RK1+MT1+RK2+Exam] (100)
 Description: The purpose of the discipline is to form with undergraduates ideas about the subject, goals and objectives of the physics of gas discharges in dense and rarefied gases; acquaint them with the main sections of the physics of gas discharge, the principles, methods and formalisms used in this field; During the study of course, master students should be competent in: 1. formulate the basic concepts of this section, to use the main physical devices for measuring of electrical quantities,\ 2. to pose and to solve simple experimental tasks of gas discharge physics, to analyze and to evaluate the getting results;to integrate the content of specific problems in physics of gas discharge with general laws of physics; 3. to apply the laws of physics of gas discharges processes for specific tasks in the field of physics and interdisciplinary boundaries with other areas of knowledge. Abstract оf discipline: The main physical phenomena of gas discharge physics, methods of their observation and experimental research. Methods for producing plasma, glow discharge, arc discharge, photoionization processes, streamer breakdown, fundamentals of the fundamental properties of the physics of nonideal plasma, the study of methods for obtaining, diagnosis, theoretical and computer analysis of the properties of nonideal (dense) plasma. Basic concepts and General laws of high energy density physics, basics of gasdischarge processes of physics as a generalization of observations, practical experience and experiment.

Methods of processing signals and images in medicine
 Type of control: [RK1+MT1+RK2+Exam] (100)
 Description: The purpose of the discipline is to teach the basic methods of analyzing biological signals and biological noise. During the course study, form undergraduates' abilities: 1. demonstrate the knowledge gained in the methods of processing signals and images in medicine as applied to the tasks of medical diagnostics and therapy; 2. to classify various methods of processing signals and images in medicine, the features and limitations of these methods; 3. use modern technologies in solving problems of signal and image processing in medicine; 4. solve scientific and practical problems of signal and image processing in medicine; 5. analyze and implement the results obtained by different methods from the point of view of the physical principles of the underlying signal and image processing in medicine; 6. to evaluate modern problems of processing signals and images in medicine, the solution of which is now actually and widely discussed in the international scientific community; 7. discuss the principle of operation of various installations for processing signals and images in medicine. 8. to substantiate in practice the set of theoretical principles and practical techniques for considering various problems of processing signals and images in medicine. Discipline summary: 1. Discipline has both fundamental and applied importance in the system of medical and physical education. It gives an idea of the basic principles of mathematical and algorithmic methods for analyzing information. 2. familiarization of undergraduates with the main ways of modeling biological objects and mastering the basic methods of analyzing biological signals and biological noise.

Optics and laser physics in medicine
 Type of control: [RK1+MT1+RK2+Exam] (100)
 Description: The purpose of the discipline is to gain knowledge about the use of lasers for diagnostics; During the study of course, master students should be competent in: 1. demonstrate the knowledge gained in optics and laser physics in relation to medical problems; 2. To classify various methods of optics and laser physics in relation to medical problems, features and limitations of these methods; 3. to use modern technologies in solving problems in optics and laser physics in relation to medicine; 4. To solve scientific and practical problems of optics and laser physics in relation to medicine; 5. analyze and implement the results obtained by different methods from the point of view of the principles underlying optics and laser physics in relation to medicine; 6. to evaluate modern problems in optics and laser physics in relation to medicine, the solution of which is now actual and widely discussed in the international scientific community; 7. to discuss the operation principle of various technical complexes used for research in optics and laser physics in medicine.\ 8. to prove in practice a set of theoretical principles and practical techniques for the consideration of various problems in optics and laser physics in relation to medicine. Discipline "Optics and laser physics in medicine" has both fundamental and applied significance in the system of medical and physical education. It provides theoretical basis for the use of medical laser devices and laser methods of research in medicine. He acquainted himself with the experimental technique in laser medicine, with various laser emitters and complex measuring instruments used in medicine This discipline is related to the following disciplines: Methods for processing images and signals in medicine. Mastering the discipline "Optics and laser physics in medicine" is necessary for theoretical and practical training in other disciplines :. The purposes of mastering the discipline "Optics and laser physics in medicine" are mastering fundamental knowledge in optics and laser medicine: a holistic view of science and its role in practical medicine; mastering the general theory questions: acquaintance with the theoretical bases of medical laser devices and laser methods of research in medicine; an exposition of the basic principles of the mechanism of the action of laser radiation on biological tissues,mastering the experimental technique in laser medicine, processing and analyzing the results obtained and teaching the skills of working with various laser emitters and complex measuring instruments practical techniques for the consideration of various problems in optics and laser physics in relation to medicine.

The problems of stability in GTR
 Type of control: [RK1+MT1+RK2+Exam] (100)
 Description: The purpose of studying of discipline is to give an idea of orbital stability and in more detail about a special type of stability in the mechanics of general relativity, such as resistance with respect to vector elements. During the study of course, master students should be competent in: 1. use of the basic concepts of differential geometry applying to general relativity 2. use of affine connection, spin connection, Fock – Ivanenko coefficients, torsion tensor, 3. formulate Einstein – Cartan gravity; 4. apply of obtained knowledge when solving problems in theory of gravity of Einstein – Cartan; 5. own: skills of applying the received knowledge at the solution of problems in the theory of gravitation. There is a brief historical review of the problem of bodies’ motion stability in general relativity and correct formulation of the problem for stability in curved spacetime. Various classes of test bodies motion in various gravitational and electromagnetic fields are investigated for stability and instability by Lyapunov and Lagrange.

Relativistic Astrophysics
 Type of control: [RK1+MT1+RK2+Exam] (100)
 Description: The purpose of the discipline to familiarize graduates with the current knowledge of the largescale structure and evolution of the universe and to give master course students a thorough understanding of the laws of the macrouniverse and to study methods of theoretical investigation of structure and evolution of the Universe. During the study of course, master students should be competent in: 1. formulate the basics of modern relativistic astrophysics; 2. solve independently applied and theoretical problems; 3. own: skills in the formulation and solution of problems on a given topic. 4. use the current knowledge of the largescale structure and evolution of the universe 5. demonstrate a thorough understanding of the laws of the macrouniverse. During the study of the discipline students will learn following aspects: The latest discoveries in astrophysics associated with the detection of exotic compact objects, dark matter and dark energy. The purpose of the course is. The subject and objects of study of relativistic astrophysics. Recent discoveries in astrophysics. The physical structure of the universe. The theory of the expanding universe. Modern problems of cosmology. To study methods of theoretical investigation of structure and evolution of the Universe.

Modern physics of dense plasma
 Type of control: [RK1+MT1+RK2+Exam] (100)
 Description: The purpose of the discipline is the development of mathematical methods for describing dense plasma and physical models that describe the fundamental properties of the plasma state of matter as a direction of modern physical science; During the study of course, master students should be competent in: 1. the basic physical models and the areas of their applicability; 2. properly articulate the basic physical models, describing the properties of the plasma state of matter; 3. an information of the relevance of the description of the various properties of the plasma and their use in scientific experiments; 4. to calculate the characteristics of the plasma according to the specified parameters; 5. to make estimates of the drift velocity of particles in plasma; to explain the influence of magnetic fields of simple configurations on the behavior of the plasma. In the framework of the course, students learn basic physical models, mathematical methods to describe the properties of the plasma state of matter and its application to the solution of specific problems.

Experimental Methods in Thermal Physics
 Type of control: [RK1+MT1+RK2+Exam] (100)
 Description: The purpose of the discipline – to give undergraduates the knowledge, skills and abilities necessary for conducting a thermophysical experiment, to acquaint them with the current state and prospects for the development of the technique of a thermophysical experiment; During the study of course, master students should be competent in: 2. to characterize the basic physical parameters and values, principles and methods of their measurements, types of measurements, types of receivers and radiation sources used in experimental Thermophysics; 3. get an idea of the prospects and problems, limitations of the use of various physical methods for the analysis of physical, mechanical, biological, geophysical phenomena and processes. 4. method of measurement of temperature, pressure, velocity, flow rate of liquid, gas, steam and other quantities; 5. make a choice of the necessary measuring instruments and assess the accuracy of the measuring systems; 6. explain the principle of operation of various devices and measuring instruments. 7. To possess practical skills of work with various measuring instruments; During the study of the discipline students will learn following aspects: Methods of measuring temperature, pressure, speed, flow, liquid, gas, and other physical quantities. Using practical calculation tasks in the workplace and in the home. Foundations of modern test and measurement equipment, methods of ensuring accuracy of measurement and control, the basic tenets of the theory of measurement, the required information on the optimal choice of measurement and control; understanding of the physical phenomena studied in graduate specialized courses; familiarize with the basic methods of thermo physical experiment; give skills of research and work with reference books.

Physics of Plasma
 Type of control: [RK1+MT+RK2+Exam] (100)
 Description: The purpose of the discipline – to form students' ideas about the subject, goals and objectives of plasma physics; to acquaint students with the fundamental questions of plasma physics in accordance with the internal logic of its development and the disclosure of the dialectical nature of the development of research in the field of plasma physics; During the study of course, master students should be competent in: 1.highdensity plasma, the effects of particle interaction between  and the collective effects of quantummechanical effects of diffraction and symmetry; 2.have skills of staging a scientific problem; 3.skills of public speaking at conferences; 4.set specific tasks of scientific research in the field of plasma physics and solve them with the help of modern information technology equipment; 5.to consider modern approaches to modeling various phenomena in the field of plasma physics and evaluation of the results obtained. Principles of ionospheric and laboratory plasma description and their analysis are given. Structure and properties of ionospheric plasma, satellite and rocket methods. Dispersion of waves in inhomogeneous plasma. High – density plasma, interparticle interaction effectscollective effects, and quantum mechanical effects of diffraction and symmetry are studied.

Real Gas and Liquid
 Type of control: [RK1+MT1+RK2+Exam] (100)
 Description: The purpose of the discipline is to study the physics of real gas and liquid, the forces and potentials of intermolecular interaction, transport phenomena in liquids for use in scientific research and solving practical problems. During the study of course, masters should be competent in: 1. understand the laws of phase transformations, the basics of kinetic theories of liquids; 2. use the basic principles of the statistical theory of dense gases; 3. apply the equations of state of matter and the most common forms of these equations; 4. to analyze the characteristics of isoperimetric gas curves for the Van der Waals equation; 5. explain the causes of the intermolecular forces, the potentials of Sutherland and LennardJones. During the study of the discipline, master students will learn following aspects: Liquid state of matter. Empirical equations of state of liquids. Methods for determining the critical parameters of a substance. Phase balance. Phase transformations. Phase diagram. Van der Waals equation and some other equations of state of real gases and liquids. Forces and potentials of intermolecular interaction. Methods of the modern approach in the study of physical processes in gases and liquids.

Physical methods of visualization in medicine
 Type of control: [RK1+MT1+RK2+Exam] (100)
 Description: The purpose of the discipline is to gain knowledge about the basic principles of visualization used in medicine, and their application in medical diagnostics, therapy and basic research on living systems. During the course study, form undergraduates' abilities: 1.to demonstrate the knowledge obtained on the physical principles of various methods of obtaining images in medicine, the features and limitations of these methods; 2. interpret the data obtained by different methods from the point of view of physical principles underlying visualization; 3. to apply their knowledge and solve the tasks of visualization methods as applied to the tasks of medical diagnostics and the study of their function; 4. apply the knowledge gained in practice. When studying a discipline, master students will study the following aspects:  Digital angiography;  Visualization using ultrasound;  Obtaining images using radioisotopes;  MRI;  ESR tomography.

Bioinformatics
 Type of control: [RK1+MT1+RK2+Exam] (100)
 Description: The purpose of the discipline  the use of computer technology for research in the field of medical physics; During the study of course, master students should be competent in: 1. demonstrate the knowledge gained in bioinformatics as applied to medical tasks; 2. to classify various methods of bioinformatics, features and limitations of these methods; 3. use modern technology in solving problems in bioinformatics; 4. solve the scientific and practical problems of bioinformatics; 5. analyze and implement the results obtained by different methods from the point of view of the principles underlying bioinformatics; 6. evaluate current problems in bioinformatics, the solution of which is now topical and widely discussed in the international scientific community; 7. discuss the principle of operation of various computer software packages used for research in bioinformatics. 8. to substantiate in practice the set of theoretical principles and practical techniques for considering various problems in bioinformatics. Discipline "Bioinformatics" has both fundamental and applied value in the system of medical and physical education. It provides an overview of network databases and ways to work with them. Methods used in biology for the analysis and comparison of nucleotide and amino acid sequences, and methods of molecular modeling are considered. This discipline is related to the following disciplines: Methods for processing images and signals in medicine. Mastering the discipline "Bioinformatics" is necessary for theoretical and practical training in other disciplines :. The objectives of the Bioinformatics discipline are to familiarize students with the basic methods and software tools for understanding biological data, modeling methods for biological objects, and various approaches that are used to create models of complex biological systems and processes.

Kinetic Theory of Gases
 Type of control: [RK1+MT1+RK2+Exam] (100)
 Description: The purpose of the discipline – the peculiarity of the course is because the “Kinetic theory of gases” as an example of a specific application of statistical methods for describing inhomogeneous gases. that it introduces such important concepts as temperature, internal energy, heat, entropy, gives a microscopic interpretation of these concepts based on the kinetic theory using the statistical method; As During the study of course, master students should be competent in: 1. Describe the laws of the kinetic theory of gases, the basics of thermodynamics, patterns of changes in some physical parameters when changing others under certain conditions; 2. to reveal the physical mechanism of the phenomenon, to analyze the change of thermodynamic parameters in specific processes; 3. To work with practical skills of calculation of thermodynamic parameters and constants using information technology. 4. Justify gas laws,explain the mathematical model of an ideal gas. 5. To study by statistical methods the properties of gases on the basis of ideas about the molecular structure of gas and a certain law of interaction between its molecules. When studying a discipline, master students will study the following aspects: Kinetic theory of gases. Precomputing almost all equilibrium properties (parameters of the equations of state) and nonequilibrium properties of gases (the transport coefficients and flows of matter, energy, momentum, entropy, electric charge). Examples of using the fundamental principles for solving equations and to obtain important practical results; depth study of the molecularkinetic theory to describe the specific problems of irreversible processes in gases, the development of the foundations of the mathematical apparatus of modern kinetic theory of gases.

Computer Modeling in Medical Physics
 Type of control: [RK1+MT1+RK2+Exam] (100)
 Description: The purpose of the discipline is to teach computer simulation skills of physical processes using various application programs, as well as develop practical modeling skills; During the study of course, master students should be competent in: 1. demonstrate the knowledge gained in computer modeling in medical physics in relation to the tasks of medical diagnostics and therapy; 2. to classify various methods of processing signals and images in medicine, the features and limitations of these methods; 3. to use modern technologies in solving problems of processing signals and images in medicine; 4. solve scientific and practical problems of processing signals and images in medicine; 5. analyze and implement the results obtained by different methods from the point of view of the physical principles underlying the processing of signals and images in medicine; 6. to assess modern problems in the processing of signals and images in medicine, the solution of which is now actual and widely discussed in the international scientific community; 7. to discuss the operation principle of various devices for processing signals and images in medicine. 8. to prove in practice a set of theoretical principles and practical techniques for the consideration of various problems in the processing of signals and images in medicine. Discipline "Computer modeling in medical physics" has both fundamental and applied value in the system of medical and physical education. It gives an idea of the basic principles and methods of computer modeling in medical physics.This discipline is related to the following disciplines: Modern achievements of magnetic resonance imaging, Nuclear magnetic resonance microtopography, Computed tomography, Emission tomography, Methods of image processing and signals in medicine. Mastering the discipline "Computer modeling in medical physics" is necessary for theoretical and practical training in other disciplines: Current achievements in magnetic resonance imaging, Nuclear magnetic resonance microtopography, Computed tomography, Emission tomography.The purposes of mastering the discipline "Computer modeling in medical physics" are familiarizing students with the basic methods of modeling biological objects and mastering the basic methods of describing and predicting the behavior of human organs under the influence of various external factors.

Computer simulation of dynamic characteristics of dense plasma
 Type of control: [RK1+MT1+RK2+Exam] (100)
 Description: The purpose of studying of discipline – study of the properties of nonideal partially and fully ionized plasma based on numerical methods; During the study of course, master students should be competent in: 1. to consider the basic properties of plasma physics and its features; 2. to various mathematical packages and computer simulation methods; 3. to create different codes for computer simulation of physical phenomena in plasma; 4.to understanding of fundamental problems in computer simulation of plasma systems; 5. to use of nonideal plasma in scientific research, development of technical projects and technological processes. Will consider various mathematical packages and numerical methods for modeling the properties of nonideal plasma; research of properties for nonideal plasmas on the basis of different computer simulation methods.

Laser technologies in medicine
 Type of control: [RK1+MT1+RK2+Exam] (100)
 Description: The purpose of the discipline is an indepth study of the fundamentals of physics and technology of lasers and their surgical and therapeutic use in medicine. During the study of course, master students should be competent in: 1. demonstrate the knowledge gained on laser technologies in medicine; 2. To classify various laser technologies in medicine, their features and limitations; 3. How to use laser technologies in medicine; 4. To solve scientific and practical problems of the application of laser technologies in medicine; 5. analyze and implement the results obtained by different laser technologies in medicine; 6. to assess current problems in laser technologies in medicine, the solution of which is now being discussed and discussed in an international scientific environment; 7. To discuss the operation principle of various technical complexes used in laser technologies in medicine. 8. to prove in practice a set of theoretical principles and practical techniques for the consideration of various problems in laser technologies in medicine. During the study of the discipline students will learn following aspects: 1. Discipline "Laser technology in medicine" has an important applied value in the system of medical and physical education. It provides theoretical and practical basis for the use of medical laser devices and technologies in medicine. He acquainted with various laser emitters and equipment used in medicine 2. This discipline is related to the following disciplines: Methods for processing images and signals in medicine. Mastering the discipline "Laser technology in medicine" is necessary for theoretical and practical training in other disciplines :. The purposes of mastering the discipline "Laser technology in medicine" are mastering practical skills in laser technologies in medicine; mastering the methods of working with medical laser devices and laser methods of research in medicine;

3D simulation of reacting flows
 Type of control: [RK1+MT1+RK2+Exam] (100)
 Description: The purpose of the discipline is to explain to the undergraduates the processes of convective heat and mass transfer occurring during the combustion of gaseous, solid and liquid fuels, to teach the calculations of the main parameters of the combustion process and the composition of combustion products, to tell about the geometry of the combustion chamber of a specific energy facility and the chemical kinetics of the processes in it, to learn how to use modern software of 3D modeling of physical and chemical processes. During the study of course, master students should be competent in: 1. basic equations that describe the nonisothermal heat and mass transfer in turbulent reacting flows; 2. apply the basic equations and calculation methods to the study of nonisothermal turbulent reacting flows occurring in the areas of real geometry; 3. practical skills needed for the calculation of the various trends occurring in the physical and chemical transformations; 4. to consider fundamental issues of physical,chemical and thermodynamic properties of the systems under consideration; 5. perform simple and complicated heat and hydraulic piping calculations. During the study of the discipline students will learn following aspects: Physical and mathematical classification of differential equations; presentation methods of differential equations in finite differences; the notion of approximation, stability and convergence of finite difference schemes; research methods on their sustainability; explicit and implicit methods for solving partial differential equations; algorithms for the calculation of explicit and implicit schemes; Examples of explicit and implicit schemes; "Approximation" or "the circuit" viscosity; the advantages and disadvantages of explicit and implicit schemes; Combined scheme; splitting principle; to show the importance of studying such flows for the various industries, including in power and the environment.

Impulse plasma dynamics
 Type of control: [RK1+MT1+RK2+Exam] (100)
 Description: The purpose of the discipline is to develop master students' skills to interpret theoretical and experimental data on plasma physics and evaluate its basic parameters. During the study of the discipline master students will learn following aspects: the principle of operation and the device of impulse installations; experimental methods for producing and studying pulsed plasma: plasma generators, plasma accelerators and diagnostic methods; understand the physical processes underlying the operation of plasma pulse installations. Will be able to assess the basic parameters of the plasma based on the calculation formulas used in plasma physics; integrate the knowledge gained from lectures, scientific journals and books into a coherent picture of the current state of the problem.

Quantum Theory of Scattering
 Type of control: [RK1+MT1+RK2+Exam] (100)
 Description: The purpose of the discipline  to give undergraduates the fundamentals of the quantum theory of scattering on the basis of a nonrelativistic equation. During the study of course, master students should be competent in: 1. formulate basic elements of scattering theory, relation between scattering amplitude and differential cross section and total cross section, 2. apply different methods of calculation of the bove mentioned characteirsitics, know the area of applicability of the methods, methods of phase scattering calculation, peculiarities of scattering in system of identical particles, peculiarities of scattering og relativistic particles; 3. calculate atomic formfactors; 4. calculate differential cross sections of scattering for cases important for practice, calculate thresholds of nuclear processes; 5. find energies necessary for birth of new particles on modern accelerators; 6. use of limit cases of large and small angles of scattering, different integrals in physics, use the conversion coefficient in quantum calculations. During the study of the discipline students will learn following aspects: Calculation of values in the born approximation for the main interaction potentials of practical importance – in the centrally symmetric potentials – in the Coulomb potential, on the shielded Coulomb potential, on the spherical pit, on the Gaussian potential, on the exponential potential and the Deltashaped interaction potential; scattering factor, partial wave method, optical theorem, Glauber multiple scattering theory, various reference systems. Consideration of the basic values in the theory of scattering – scattering amplitude and differential crosssection of scattering and methods of their calculation.

Methods of scientific research in thermal physics
 Type of control: [RK1+MT1+RK2+Exam] (100)
 Description: The purpose of the discipline is to study the structure and content of gas in the system of thermophysical processes, the possibility of research in the gas phase, patterns of thermophysical phenomena, quantify the physical processes. During the study of course, master students should be competent in: 1. experimental methods for measuring thermal quantities; 2. make a choice of the necessary measurement tools and estimate precision measuring systems; 3 Possess practical skills for experimental investigation of physical phenomena in thermal physics; 4 work with instruments and equipment of a modern physical laboratory; 5 explain the main observable natural and technogenic phenomena and effects from the standpoint of fundamental physical interactions. The main requirements in the design of experimental facilities; the study of laminar and turbulent boundary layers; measurement of the coefficient of hydraulic resistance; Preston method; dynamics of viscous fluid; vortexfree movement of an ideal incompressible fluid; formation of undergraduates skills of using special issues of the course "Methods of scientific research in Thermophysics", understanding the basics of physical phenomena, familiarization with the basic methods of thermophysical experiment; skills of research and work with reference literature.

Тhe problem of motion of bodies in general relativity
 Type of control: [RK1+MT1+RK2+Exam] (100)
 Description: The purpose of the discipline to give graduates understanding of the basic problems and methods of mechanics of Einstein's theory of gravity. During the study of course, master students should be competent in: 1. the mathematical formalism of general relativity (GR) 2. the main ideas of this physical theory and the area of its further applications; 3. work independently with the main issues and methods of mechanics of Einstein's theory of gravity; 4. own: the Fock methods  an important tool for deriving the equations of motion for the finite mass of the gravitational field from the equations of Einstein. 5. formulate problems of Einstein theory of gravity During the study of the discipline students will learn following aspects: Mechanics of the general theory of relativity. Schwarzschild metric. Kerr metric. Approximate metric. Condition of harmonicity. Expansion of the metric by Fock. The solution of Einstein's equations in the quasistationary case by Fock approximation. The problem of LenseThirring. Consideration of the exact and approximate solutions of Einstein's equation, as well as their practical application to applied problems of astrophysics and cosmology.

Сollisional processes in a dense plasma
 Type of control: [RK1+MT1+RK2+Exam] (100)
 Description: The purpose of the discipline – study of elementary processes in partially ionized plasma and their practical importance in the creation of gas lasers and other installations During the study of course, master students should be competent in: 1. analyze of collision processes in dense plasmas; 2. to distinguish features of nature of collisions in dalnodeystvuyushchy Coulomb interaction of the facing particles; 3.investigate collisional processes studied using the methods in this course; 4. to integrate the equations for finding the elastic and inelastic scattering; 5. using computer programs for plotting cross sections. During the study of the discipline master students will learn following aspects:  collisional processes in dense plasma; features of the nature of collisions in the longrange Coulomb interaction of colliding particles;  can explore collision processes using the methods studied in this course; integrate the equations to find the cross sections for elastic and inelastic scattering; possess the skills to use computer programs for graphic construction of scattering sections.

Experimental methods in lowtemperature physics
 Type of control: [RK1+MT1+RK2+Exam] (100)
 Description: The purpose of the discipline is to study the modern methods of lowtemperature research, to consider the physical bases for obtaining and measuring cryogenic temperatures, the thermodynamic principles for constructing cryogenic systems, the classical schemes for organizing cryogenic refrigerators and liquefiers and methods for calculating their characteristics, the physical fundamentals of work and the technical design of gas cryogenic machines and throttle microcryogenic systems. Analyze the trends and development prospects of these branches of technology. Consider the fundamental principles of designing cryostats and cryogenic equipment, as well as features of lowtemperature physical experiments. Analyze the trends and development prospects of these branches of technology. Consider the fundamental principles of designing cryostats and cryogenic equipment, as well as features of lowtemperature physical experiments. During the study of course, master students should be competent in: 1. the history of development of lowtemperature research; basic methods for low and very low temperatures; 2. basic methods for measuring low and very low temperatures; 3. mechanical, thermal and electromagnetic properties of materials at low and very low temperatures; 4. the main methods of obtaining and measuring the vacuum; physical foundations of modern cryotechnology; 5. design and manufacture the main components cryogenic vacuum systems use liquid nitrogen for cryogenic vacuum; 6. manufactures and grading of lowtemperature sensors; 7. to carry out lowtemperature measurements in the automatic mode; 8. use IR spectroscopic methods of analysis of substances at low temperatures; formulate and solve simple experimental problems of low temperature physics, properly handle, analyze and evaluate the results obtained; 9. Possess: means of measurements in accordance with the standards (technical regulations), and analyze the results. During the study of the discipline students will learn following aspects: The fundamentals of low and very low temperatures. Fundamentals of lowtemperature thermometry. Methods of measurement at low temperatures. Methods for producing low and very low temperatures. Fundamentals of vacuum technology. The properties of materials at low temperatures. Acquisition of knowledge of undergraduates experimental research methods in the range of low and very low temperatures, the physical foundations of thermodynamics, processes and phenomena that take place in a wide range of thermodynamic parameters of state of matter.

Dissertation Writing
 Type of control: Защита НИР
 Description:

Research Seminar I
 Type of control: Защита НИР
 Description: The main purpose of "Research Seminar": the formation of master students in the skills of scientific research work. During the study of course, master student's should be competent in: 1. is able to competently substantiate the main directions of scientific research on the topic of dissertational work; 2. formulate a research problem, put a scientific problem and choose appropriate research methods; 3. can apply theoretical and experimental research methods in professional activity; 4. analyze the results of scientific research at each stage of the dissertation preparation; 5. are able to evaluate and draw conclusions on the main provisions of their research activities.

Research Seminar II
 Type of control: Защита НИР
 Description: The main purpose of "Research Seminar": the formation of master students in the skills of scientific research work. During the study of course, master student's should be competent in: 1. is able to competently substantiate the main directions of scientific research on the topic of dissertational work; 2. formulate a research problem, put a scientific problem and choose appropriate research methods; 3. can apply theoretical and experimental research methods in professional activity; 4. analyze the results of scientific research at each stage of the dissertation preparation; 5. are able to evaluate and draw conclusions on the main provisions of their research activities.

Research Seminar III
 Type of control: Защита НИР
 Description:

Scientific Internship
 Type of control: Защита НИР
 Description: The main purpose of "Scientific Internship": is the formation in the students of the ability to independently conduct research and development in the professional sphere using modern research methods and information and communication technologies on the basis of a foreign university. During the study of course, student should be competent in:  to substantiate the fundamentals of the methodology for performing scientific research, planning and organizing a scientific experiment, processing scientific data;  to argue methods of solving research and practical problems, including in interdisciplinary areas;  can analyze alternative solutions to research and practical problems and assess the potential benefits of implementing these options;  apply theoretical knowledge on methods of collecting, storing, processing and transmitting information using modern computer technologies;  choose the methods of presentation and methods of information transfer for different contingents of listeners.

Research practice
 Type of control: Защита практики
 Description: The main purpose of the discipline: the formation of pedagogical competence, the ability of pedagogical activity in universities and colleges based on the knowledge of the didactics of the higher school, the theory of education and management of education, analysis and selfassessment of teaching. During the study of course, master students should be competent in:  classify teaching methods based on criteria: traditionalistic  innovation; activity of cognitive activity; didactic goal and focus on results;  apply strategies and methods of training and education adequate to the goals;  develop research projects on topical issues of education and present the results in the form of presentations, articles, etc.;  describe different approaches to university management (university management  linear, structural, matrix): structure, quality, reputation;  evaluate and manage the processes of the organization of education, aimed at improving the structure, quality, reputation based on modern management approaches;  develop the provisions of the academic and research policy of the organization of education.

Teaching Internship
 Type of control: Защита практики
 Description: The purpose of teaching practice is to prepare for scientific and pedagogical activities in higher education, the acquisition and consolidation of practical skills for the implementation of the teaching and educational process in higher education, including the teaching of special disciplines, the organization of educational activities of students, scientific and methodological work on the subject.As a result of pedagogical practice, the undergraduate will have the skills of structuring and transforming scientific knowledge into educational material, oral and written presentation of the subject material, a variety of modern educational technologies, methods of drawing up tasks, exercises, etc.

Publication in the Proceedings of International Conferences
 Type of control: Защита НИР
 Description: The main purpose of "Publication in the Proceedings of International Conferences": is the formation of master candidates in the possibility of presenting the results of research work to the scientific community, receiving feedback, and exchanging experience in the field of professional activity. During the study of course, master student's should be competent in: 1. demonstrate current trends in scientific research; 2. to argue the annotated results of research in scientific journals, materials of international conferences and symposia; 3. they can apply new, scientifically grounded, theoretical or experimental results that allow solving a theoretical and applied problem; 4. analyze scientific results, the data of their colleagues and opponents in the sphere of the chosen professional activity; 5. generate ideas for the use of proposed developments in scientific research of the professional field of activity.