Offered courses

Division of Experimental and Theoretical Physics

• Chair of Theoretical Physics
• Chair of Mathematics
• Chair of Molecular Physics
• Chair of General Physics and Molecular Electronics
• Chair of Biophysics
• Chair of General Physics
• Chair of Quantum Statistics and Field Theory
• Chair of Medical Physics

Division of Solid State Physics

• Chair of Solid State Physics
• Chair of Semiconductor Physics
• Chair of Polymer and Crystal Physics
• Chair of Magnetism
• Chair of Low-Temperature Physics and Superconductivity
• Chair of General Physics and Magnetoordered Media
• Chair of Condensed Matter Physics

Division of Radiophysics and Electronics

• Chair of Physics of Oscillations
• Chair of General Physics and Wave Processes
• Chair of Acoustics
• Chair of Radiophysics
• Chair of Quantum Electronics
• Chair of Physical Electronics

Division of Nuclear Physics

• Chair of Atomic and Plasma Physics and Microelectronics
• Chair of Cosmic Rays and Space Physics
• Chair of Optics and Spectroscopy
• Chair of Physics of Atomic Nuclei and Quantum Collisions Theory
• Chair of Quantum Theory and High-Energy Physics
• Chair of Physics of Elementary Particles
• Chair of Physics of High-energy Accelerators
• Chair of General Nuclear Physics
• Chair of Neutronography

Division of Geophysics

• Chair of Physics of Earth
• Chair of Physics of Sea and Inland Waters
• Chair of Physics of Atmosphere
• Chair of Computer Methods in Physics

Division of Astronomy

• Chair of Astrophysics and Stellar Astronomy
• Chair of Celestial Mechanics, Astrometry and Gravimetry
• Chair of Experimental Astronomy

Division of Experimental and Theoretical Physics

Chair of Theoretical Physics

• Anomalies in quantum theory
• Classical and quantized fields in curved space-time
• Classical field theory
• Classical theory of gravity
• Field theory and quantum gravity
• Fundamental particles and interaction
• Geometrical methods of the field theory
• Geometry and physics
• Group theory and its applications
• Interaction of particles with electromagnetic fields
• Mathematical methods in quantum field theory
• Physics of high energies
• Quantum field theory
• Quantum field theory and statistical physics
• Quantum theory of gravity and superstring theory
• Supersymmetry
• Theory of fundamental interaction

Chair of Mathematics

Courses in General Mathematics

• Analytical theory of differential equations
• Applications of spectral theory in mathematical physics
• Asymptotical methods
• Basics in geometry and topology
• Basics of algebra and differential geometry
• Basics of the categories theory
• Complex analysis. Advanced course
• Effective methods in boundary value problems
• Elliptic equations
• Extremal problems
• Functional analysis
• Geometrical applications in physics
• Integral equations
• Inverse problems of mathematical physics
• Mathematical aspects of diffraction theory
• Mathematical theory of wave-guides
• Method of differential inequalities
• Non-linear waves
• Parabolic equations
• Special functions of mathematical physics

Courses in Numerical Methods and Computer Modelling

• Computer physics
• Computer science. Introduction
• Dynamical adaptive methods in equations of mathematical physics
• Finite difference methods in computer physics
• Mathematical models of plasma physics
• Mathematical models of quantum mechanics and statistical physics
• Numerical methods in MHD
• Numerical methods. Advanced course
• Numerical methods. Introduction

Chair of Molecular Physics

• Computer methods in solving of physical problems
• Diffraction methods in crystal research
• Dynamics of plasma and gases
• Electrical properties of condensed media
• Hydrodynamics of relaxing and reacting media
• Management in scientific research
• Modern problems of molecular physics
• Non-equilibrium thermodynamics
• Optical and spectral methods in research of anisotropic fluids
• Physical hydrodynamics
• Physics and visualization of flows
• Physics of combustion and explosion
• Physics of liquids
• Physics of molecules
• Relaxation processes in gases
• Solid-state physics
• Thermodynamics

Chair of General Physics and Molecular Electronics

• Experimental methods in solid state research
• Experimental methods of probe microscopy
• Introduction to laser technologies
• Introduction to solid-state physics
• Investigation techniques for solid surfaces and interfaces
• Magnetic nanostructures
• Non-linear optical phenomena in condensed matter
• Optics of solid state
• Phase transitions on solid-state surfaces
• Physical bases of molecular microelectronics. Parts I&II
• Physical foundations of microelectronics
• Physics of semiconductors
• Physics of solids sensors for molecular analysis
• Physics of solid-state surfaces. Parts I&II
• Radiation physics of solid state
• Radiospectroscopy of solid-state and low-dimensional systems
• Structure and methods of research of ordered molecular ensembles
• X-ray research of thin organic films

Chair of Biophysics

• Basics of general chemistry
• Basics of human anatomy and histology
• Basics of immunology
• Biochemistry
• Biophysical chemistry
• Biophysics of photosynthesis and ecology
• Calculation techniques in studies of electronic properties of complex molecules
• Cell biophysics
• Condensed matter physics for biophysicists
• Formal and enzymatic kinetics
• General biology
• General physiology
• Immunochemical analysis
• Information thermodynamics in biophysics
• Introduction in biophysics and medical physics
• Introduction in general biology and biophysics
• Magnetic properties of molecules. Methods of magnetic resonance spectroscopy in biophysical and biomedical research
• Medical biophysics: cellular and molecular aspects of pathogenesis of diseases
• Molecular biology
• Non-linear dynamics and mathematical modelling of biological systems
• Optical properties of complex molecules
• Physical chemistry
• Physical chemistry of surfaces of molecular structures and nanostructures
• Physics of biopolymers
• Quantum chemistry and structure of molecules
• Radioelectronics and computerized data-acquisition systems in biophysical experiment
• Statistical methods in biophysics
• Thermodynamics of biological processes and selected chapters of bioenergetics

Chair of General Physics

• Condensed media: from structural units to living objects
• Foundations of Moessbauer spectroscopy
• Introduction into physics of particle interactions at superhigh energies
• Introduction to physics of pulsed reversal processes in magnetics
• Magnetooptical phenomena in magnetoordered solids
• Micromagnetism of magnetics
• Modern methods of Moessbauer data processing
• Modern trends in self-organization of non-equilibrium non-linear open systems
• Molecular luminescence
• Molecular spectra and structure of molecules
• Molecular spectroscopy
• Multilayered optics
• Optical methods of research of complex molecular systems
• Optics of anisotropic media
• Optics of wave beams and pulses
• Practical problems of teaching physics
• Principles of methodology of physics teaching
• Problems of relativistic electrodynamics
• Radiospectroscopy of magnetic materials
• Spectroscopic methods in biophysics and ecology
• Topical issues of cosmic ray physics
• Transport of superhigh energy particles through various media

Chair of Quantum Statistics and Field Theory

• Asymptotic methods in statistical physics and quantum field theory
• Classical gauge fields
• Condensed matter physics
• Dispersion methods in elementary particle physics
• Gasodynamics of superliquids
• Geometrical methods in high-energy physics
• Gomological algebra methods in quantum statistics
• Introduction to Maslov semiclassical methods
• Introduction to non-linear waves theory
• Introduction to quantum theory of spontaneous processes
• Introduction to statistical mechanics
• Introduction to the theory of early Universe
• Lattice quantum field theory
• Mathematical methods of statistical mechanics of model systems
• Method of secondary quantization and polaron theory
• Numerical methods in quantum physics
• Optimization problems in mathematical physics
• Quantum fields
• Quantum scattering theory
• Quantum statistics
• Supersymmetry models of elementary particles
• Theory of many-particle systems

Chair of Medical Physics

• Basics of anatomy, histology and cytology
• Basics of gene therapy
• Basics of introscopy (X-ray, nuclear magnetic resonance, acoustic, and laser tomography)
• Basics of physiology and pathophysiology
• Basics of theory of oscillations and waves
• General and medical acoustics
• General biology and biophysics
• General medicine
• General physical chemistry
• Information technology and statistical methods in medicine
• Introduction to biophysics of non-ionizing radiation
• Introduction to medical physics
• Laser technologies in ophthalmology
• Mathematical methods of digital image and signal processing
• Mathematical modelling of living systems
• Medical accelerators
• Medical biochemistry
• Medical electronics and pickups
• Molecular cell biology
• Molecular pathology and diagnostics
• Optics and laser physics in medicine
• Optics of blood
• Physical foundations of biotissue engineering
• Physical principles and techniques of proton and neutron radiation therapy
• Physical principles of radiation therapy
• Physical research methods in biology, and medicine
• Physiological optics
• Principles of chemistry
• Radiation physics, diagnostics and therapy
• Remote biomodelling and basics of implantology
• Synchrotron emission in medicine

Division of Solid State Physics

Chair of Solid State Physics

• Actual problems of solid-state physics
• Computers in solid-state research and information technologies
• Diffractional and X-ray structural analysis. Parts I&II
• Dynamical theory of X-ray scattering
• Electron microscopy of solids and biological objects
• Introduction to crystallography and techniques of structural experiments
• Methods of X-ray analysis
• Microscopical theory of metals and allows
• Modern problems of solid-state physics
• Nuclear physics of solid state
• Phase transitions in metal allows
• Physics of condensed systems
• Physics of real crystal systems
• Quantum solid state theory
• Rontgenography of condensed matter
• Secondary processes in X-ray optics
• Solid-state physics
• Structural physics of allows with shape memory effects
• Structural physics of high-temperature superconductors
• Structural physics of rare-earth intermetallics
• Synchrotron research in solid-state physics
• Synergetic aspects in solid-state physics

Chair of Semiconductor Physics

• Cathodoluminescent methods of semiconductor investigation
• Computers in experimental physics of semiconductors
• Fundamentals of material science and technology of semiconductors
• Introduction to condensed matter physics
• Kinetics phenomena in semiconductors
• Modern problems of semiconductor physics
• Non-linear optics of semiconductors and low-dimensional semiconductor structures
• Optical phenomena in semiconductors
• Photoelectrical phenomena in semiconductors
• Physics of non-ordered semiconductors
• Physics of semiconductor devices
• Physics of semiconductors
• Radiation effects in semiconductors
• Theory of semiconductors
• Two-dimensional structures and superlattices in semiconductors

Chair of Polymer and Crystal Physics

• Additional topics of crystal physics
• Analytical nanoscopy
• Associating polymers
• Autowaves in complex physical-chemical systems
• Computer modelling of polymer systems
• Crystal growth
• Electrophysical properties of dielectrics
• Ellipsometry of thin organic films
• Fundamentals of crystal physics
• Fundamentals of theory of disordered condensed systems
• Introduction to crystal physics
• Introduction to dynamic theory of chaos
• Introduction to polymer science
• Mathematical aspects of data processing in physical experiment
• Mathematical methods in polymer and crystal science
• Methods and applications of theory of phase transitions in polymer physics
• Methods of computer simulation in statistical physics
• Modern methods of polymer synthesis
• Modern Monte-Carlo methods for modelling of polymers
• Modern problems of polymer and crystal physics
• Molecular kinetics and nanomechanics
• Non-linear optics of crystals and polymers
• Optical methods of condensed matter investigation
• Optics of crystals and polymers
• Personal computers in physics research
• Physical acoustics of polymers and crystals
• Physical methods of investigation of structure of substances: small angle scattering and fluorescence spectroscopy
• Physical properties and structure of polymers
• Physics of biopolymers
• Physics of colloids
• Physics of liquid crystals
• Quantum chemistry
• Self-organization in polymer systems
• Statistical methods in chemical physics of polymers
• Statistical physics of macromolecules
• Statistical physics of polymers on surface
• Structural concepts in polymer science
• Structural electronography
• Structure and methods of investigation of ordered molecular ensembles
• Synthesis of polymers with complex spatial architecture

Chair of Magnetism

• Advanced chapters of magnetism theory. Parts I&II
• Computerized data acquisition systems in physical experiments and numerical methods
• Critical phenomena and magnetic phase transformations
• Electronic structure and properties of transition metals
• Experimental methods in magnetism
• Experimental setup of modern magnetic laboratory
• Introduction to physics of magnetic phenomena
• Macromolecular magnetism and magnetism of biological micro-objects
• Magnetic materials
• Magnetooptical spectroscopy
• Magnetooptics of ferromagnetics
• Physics of condensed matters
• Physics of magnetic phenomena. Parts I–IV
• Quantum models of magnetism
• Quantum theory of solids. Parts I&II
• Transport phenomena in ferromagnetic materials and alloys

Chair of Low-Temperature Physics and Superconductivity

• Computer methods in experimental physics
• Condensed matter physics
• Cooperative phenomena in solids
• Elastic theory and thermal properties of solids
• Elementary excitations in crystals
• High-T_c superconductivity
• Introduction to low-temperature physics
• Low-temperature phase transitions
• Methods of quantum field theory in condensed matter physics
• Modern problems of low temperature physics
• Optoelectronics
• Physics of low-dimensional systems
• Physics of narrow-gap semiconductors
• Physics of semiconductors
• Physics of superconductivity
• Physics phenomena in non-crystal matter
• Physics phenomena in non-ordered matter
• Quantum theory of magnetism
• Radiospectroscopy
• Theoretical physics of low temperatures
• Tunnelling effects in superconductors

Chair of General Physics and Magnetoordered Media

• Computerized data acquisition systems in modern experimental physics
• Contemporary experimental methods in solid-state physics
• Crystal growth and contemporary methods of materials preparation
• Crystallography and representations of crystallographic groups
• Introduction to condensed matter physics
• Magnetic dielectrics and semiconductors
• Magnetic ions in the electric crystalline field
• Magnetic structures
• Magnetism of nanosystems
• Modern magnetic materials
• Modern problems of condensed matter physics
• Phase transitions and renormalization group
• Physics of ferroelectrics
• Physics of magnetic phenomena. Part 1. Weak magnetic substances
• Physics of magnetic phenomena. Part 2. Exchange interactions in spin-ordered materials
• Physics of magnetic phenomena. Part 3. Magnetic anisotropy. Magnetostriction. Domain structure and magnetization
• Physics of magnetic phenomena. Part 4. Dynamic properties of magnetic substances
• Physics of rare-earth metals and alloys
• Quantum theory of solid state

Chair of Condensed Matter Physics

• Dielectric and magnetic properties of solids
• Electron properties of disordered systems
• Electrons in disordered media
• Group theory in solid-state physics
• Interacting electrons in normal metals
• Introduction to physics of superconductors
• Modern aspects of solid-state physics
• Physical fundamentals of modern methods of investigations of real structure of crystals
• Physics of low-dimensional systems
• Physics of metals
• Physics of semiconductors
• Quantum Hall effect
• Spectroscopy of semiconductors and dielectrics
• X-ray analysis

Division of Radiophysics and Electronics

Chair of Physics of Oscillations

• Computer methods in physical research
• Distributed oscillatory systems
• Electronics of semiconductor devices
• Fluctuations in physical systems
• Foundation of optoelectronics
• Group theory in physics of oscillations
• Introduction to quantum measurements
• Introduction to solid-state physics
• Introduction to theory of dynamic systems
• Measuring methods based on quantum effects
• Non-linear oscillation and wave phenomena in physics
• Optical processing of information
• Oscillation systems with small dissipation
• Parametric and self-oscillating systems
• Physics foundation of electrical and acoustical optics
• Pulsed signals and transient processes in electronics systems
• Quantum communications and quantum calculations
• Quantum oscillating systems
• Quantum theory of measurements and checking of hypotheses
• Semiconductor lasers and optic waveguides
• Statistical analysis and signal processing in physics measurements
• Theory of oscillations
• Waves in guiding structures

Chair of General Physics and Wave Processes

• Atomic species and plasma in strong light fields
• Autowave processes
• Coherent control and time-resolved spectroscopy
• Dynamics of biomolecules: Laser spectroscopy and mathematical modelling
• Dynamics of lasers
• Fundamentals of photonics and optical technologies
• Fundamentals of quantum electronics
• High-temperature femtosecond laser-produced plasma
• Interaction of laser radiation with molecular gases
• Laser diagnostics in biology and medicine
• Laser optoacoustics
• Lasers and non-linear optics
• Matter in strong light field
• Modern computer technologies in detection, data-acquisition and data-processing, and control systems
• Modern problems of adaptive optics
• Non-linear laser spectroscopy
• Non-linear polarization optics
• Non-linear waves and non-linear optics
• Optical data processing
• Optics of conducting polymers and nanomaterials
• Optics of randomly inhomogeneous media
• Optics of ultrashort pulses
• Physics of lasers
• Physics of solids and phase transition
• Quantum random processes
• Resonant non-linear optical processes
• Statistical and quantum optics
• Statistical radiophysics

Chair of Acoustics

• Acoustic non-linearity of solids
• Acoustics of ocean for acousticians
• Acoustics of ocean. Part I. General hydroacoustics
• Acoustics of ocean. Part II. Statistical hydroacoustics
• Dynamics of continua for radiophysicists
• Foundation of vector-phase measurements of acoustical fields
• Introduction to acoustics
• Inverse scattering problems in acoustics
• Methods of hydroacoustical measurements
• Microwave acoustics and acoustoelectronics
• Non-linear hydroacoustics
• Numerical methods in acoustics
• Physical acoustics. Parts I&II
• Physics of noise and vibrations
• Sound sources
• Theoretical foundations of acoustics. Part 1. Radiation and scattering of acoustical waves
• Theoretical foundations of acoustics. Part 2. Acoustical wave propagation in bounded media
• Ultrasonic methods in solid-state physics

Chair of Radiophysics

• Bifurcations and catastrophes
• Diffractions and dispersion phenomenon in non-linear media
• Digital systems and processes
• Electron beam interaction with electromagnetic field
• Fiber optics
• Microwave solid-state electronics
• Millimetric waves
• Non-linear microwave electronics
• Non-linear waves
• Numerical methods in radiophysics
• Numerical modelling in non-linear electrodynamics
• Physics of microwaves
• Propagation of electromagnetic waves in troposphere
• Quantum phenomena in radiophysics
• Radiospectroscopy
• Radiowaves propagation in Earth ionosphere
• Submillimeter radiospectroscopy
• Wave theory

Chair of Quantum Electronics

• Correlation spectroscopy
• Elementary excitations in solid
• Interaction of electromagnetic radiation with matter
• Kinetics of complex systems
• Laser physics
• Laser spectroscopy
• Lasers in ecology
• Macroscopic quantum effects
• Non-linear dynamics
• Non-linear optics
• Physical basics of quantum information
• Physics of condensed state of matter
• Physics of nanostructures and mesoscopic phenomena
• Quantum electronics
• Quantum optics. Parts I&II
• Scanning probe spectroscopy and basics of nanoelectronics
• Theoretical basics of quantum radiophysics. Parts I&II
• Theory of non-linear waves
• Theory of oscillations

Chair of Physical Electronics

• Additional chapters of solid-state electronics
• Diagnostic of plasma
• Dynamics of radiating plasma
• Electrodynamics of plasma and plasma-like media. Parts I&II
• Electron spectroscopy and microanalysis
• Electron spectroscopy of solid state
• Elementary processes and kinetics of low-temperature plasma
• Emission phenomena at surfaces
• Inelastic ion-surface interaction
• Interactions of electromagnetic waves with plasma
• Introduction in physics of radiating plasma
• Novel trends in solid-state physics
• Oscillations and waves in plasma media
• Physical foundations of gas discharge
• Physical foundations of nano- and molecular electronics
• Physical foundations of solid-state electronics
• Physics of boundary layers of plasma
• Physics of intense relativistic electron beams
• Practical semiconductor electronics
• Theory of plasma instabilities

Division of Nuclear Physics

Chair of Atomic and Plasma Physics and Microelectronics

• Condensed matter physics
• Electrodynamics of superconductors
• Experimental methods of atomic and molecular research
• Foundations of electronics and theory of oscillations
• Foundations of superconductive electronics
• Interaction of electromagnetic radiation with plasma
• Introduction into single-electronics
• Introduction to physics of superconductivity
• Introduction to quantum field theory
• Introduction to superconductivity and single-electronics effects
• Non-equilibrium processes in gaseous media
• Oscillations and waves in plasma
• Physical processes in intense light fields
• Physics and dynamics of Josephson junctions
• Physics of atomic collisions
• Physics of atoms and molecules
• Physics of fundamental interactions
• Physics of low-temperature plasma
• Plasma spectroscopy
• Problems of energetic and plasma physics
• Quantum chemistry
• Quantum phenonena in solid state physics
• Radiophysics and electronics
• Transport of particles and quanta through matter

Chair of Cosmic Rays and Space Physics

• Cosmic ray astrophysics
• Cosmic ray research techniques
• Electronic devices in nuclear physics
• Energetic particles and plasma in magnetospheres of planets
• Experimental techniques in space physics
• Fundamental interactions and cosmic rays
• High-energy gamma-astronomy
• Interactions of radiation with matter
• Introduction to cosmic ray physics
• Modern non-linear techniques for analysis of complex systems
• Neutrino and neutrino astrophysics
• Physics of high-energy and elementary particles
• Physics of near-Earth and interplanetary space
• Solid-body aspects of nuclear physics
• Space plasma physics
• Techniques of physical experiment
• Ultra-high energy cosmic rays
• X-ray and gamma-astronomy

Chair of Optics and Spectroscopy

• Applied computer optics
• Computer methods in processing experimental results and modelling physical problems
• Condensed matter physics
• Experimental methods in optics
• Foundations of physical optics
• Interaction of radiation with matter and non-linear optics
• Introduction to integrated and fiber optics
• Introduction to neural networks and genetic algorithms
• Kinetics of molecular media
• Laser in medicine
• Laser spectroscopy
• Luminescence of crystals
• Luminescence of rare-earth ions
• Methods of analyzing stochastic signals and structures
• Molecular luminescence
• Non-radiation energy transfer in condensed matter
• Optical instruments in synchrotron radiation channels
• Optical methods in informatics
• Optical spectra of atoms and molecules
• Optics of coherent radiation
• Physics of fundamental interactions
• Physics of lasers
• Secondary processes in dielectric crystals
• Solid-state spectroscopy
• Spectroscopy of atoms and atomic collisions
• Statistical optics
• Synchrotron radiation and its applications
• Synchrotron radiation in biology and medicine
• Theory of synchrotron radiation
• Topics in modern optics and spectroscopy
• VUV-spectroscopy methods
• X-ray optics

Chair of Physics of Atomic Nuclei and Quantum Collisions Theory

• Additional questions of scattering theory
• Advanced chapters of nuclear reactions
• Computer methods in collision theory
• Condensed matter physics
• Density matrix
• Experimental methods of nuclear physics
• Hadron interactions
• Hyperfine interactions in nuclear physics
• Interaction of particles and radiation with matter
• Kinematics of elementary processes
• Nuclear physics at intermediate energy
• Nuclear physics of heavy ions
• Nuclear reactions
• Physics of electromagnetic interaction
• Physics of mesoatomic processes
• Physics of nuclear fission
• Quantum theory of collisions
• Spectroscopy and structure of hadrons
• Structure of nucleus

Chair of Quantum Theory and High-Energy Physics

• Additional chapters of classical electrodynamics
• Computer methods in theoretical physics
• Dynamical equations in quantum field theory
• Foundations of standard model
• Gauge field theory
• Gravitation theory
• Group theory
• Introduction to physics of elementary particles
• Introduction to theory of gravitation
• Methods of contemporary quantum field theory
• Modern theoretical problems of contemporary high-energy physics
• Numerical methods in theoretical physics
• Quantum chromodynamics
• Quantum field theory
• Renormalization theory and renormgroup theory
• Solitons, instantons, and quark bags
• System of analytical calculations "MAXIMA"
• Theory of quantum calculations

Chair of Physics of Elementary Particles

• Additional topics of elementary particles kinematics
• Applied programs for particles interaction and registration simulation
• Bases of computing and information technologies
• Computerized data acquisition systems in physical experiments
• Detectors of high-energy particles
• Electronic methods and automation of physics experiments
• Electronics in high-energy physics
• Electroweak interaction (experiment)
• Feynman's diagrams
• Introduction to physics of the Standard Model
• Introduction to quantum field theory
• Kinematics of decays and interactions of elementary particles
• Main problems of off-line processing in experimental physics of high-energies
• Methods of processing and modelling in physics experiment
• Methods of programming in high-energy physics
• Methods on nuclear particles detection
• Modern methods of particles registration
• Nuclear electronics
• Numerical methods in physics
• Passage of high-energy particles through matter
• Phenomenology of high-energy physics
• Phenomenology of strong interaction
• Physics of condensed matter
• Physics of elementary particles
• Physics of weak interaction
• Quantum chromodynamics
• Quantum field theory
• Quark-hadron physics
• Research of high-energy hadrons interactions
• Results of experiment processing automation
• Standard model and its extension at high-energy processes
• Statistical methods of measurement results processing in nuclear physics
• Structure of nucleus
• Techniques of physical experiments
• Theory of numerical methods

Chair of Physics of High-energy Accelerators

• Biophysics fundamentals of physiological processes
• Computer tomography
• Computerized control systems of particle accelerators
• Fundamentals of particle accelerator physics
• Interaction of radiation with heterogeneous mediums
• Interaction of radiation with matter
• Introduction to medical physics
• Introduction to physics of particle accelerators
• Main particle accelerator centres of the world. Parts I&II
• Mathematical methods of experimental data analysis
• Medical fundamentals of beam therapy
• Non-ionizing radiation in biomedical diagnostics
• Nuclear medicine
• Physics fundamentals and engineering of proton beam therapy
• Physics of cancer
• Radiation problem of particle accelerators
• Radiobiology
• Systems of particle accelerators

Chair of General Nuclear Physics

• Accelerators in nuclear experiment
• Atomic collisions in solids and computer simulation
• Atomic nuclei
• Condensed matter physics
• Electromagnetic radiation of electrons
• Electroweak interaction
• Foundation of quantum chemistry
• Hadrons and nuclei
• Inertial controlled thermonuclear fusion
• Interaction of low-energy Ions with solid-state surface
• Interaction of photons and electrons with atomic nuclei
• Interaction of radiation with matter. Parts I&II
• Ion spectroscopy of surface
• Mathematical statistics in nuclear physics
• Models of atomic nuclei
• Nuclear physics of high energies
• Nuclear reactions
• Nuclear resonance fluorescence
• Orientation effects in crystals
• Origin of elements
• Photonuclear reactions
• Physics of atomic collusions
• Physics of high-current accelerators
• Physics of interface and low-dimensional structure
• Physics of ion-atomic collisions
• Physics of quarks
• Physics of X-ray radiators. X-ray lasers
• Quantum field theory
• Quantum physics of metals
• Radiation ecology
• Size and shape of atomic nuclei

Chair of Neutronography

• Computer methods for experimental data processing in solid-state physics
• Condensed matter physics
• Condensed matter spectroscopy with synchrotron radiation beams. Parts I&II
• Crystallography and fundamentals of structural analysis
• Diffraction structural analysis
• Experimental methods of condensed matter research
• Fundamentals of modern texture analysis of materials
• Introduction to neutron physics
• Low-temperature physics and techniques
• Mathematical data processing in nuclear-physical experiments for condensed matter research
• Methods for condensed matter research
• Modern problems of condensed matter physics
• Neutron activation analysis
• Neutron optics
• Physical methods in molecular biology
• Quantum theory of solid states
• Slow neutrons in physical research
• Structural neutronography
• Synchrotron radiation for condensed matter research
• Techniques and methods in neutron experiments

Division of Geophysics

Chair of Physics of Earth

• Early evolution and gravitation field of the Earth
• Electromagnetic field of the Earth
• General geology
• General geophysics and ecology
• Geodynamics
• Geomagnetism
• Geothermics
• Inner structure and physics of the Earth
• Inverse problems of geophysics
• Magnetism of rocs
• Mechanics of deformable media
• Mechanics of earthquake centre
• Modern geophysics methods of ocean bottom research
• Physics bases of earthquakes forecast
• Physics geology and bases of geotectonics
• Physics of the Earth
• Seismology: structure of the Earth on seismic date
• Seismometry
• Thermophysics of minerals and rocks

Chair of Physics of Sea and Inland Waters

• Atmosphere–ocean interaction
• Dynamics and ecology of inland reservoirs
• Dynamics and ecology of inland waters
• Ecological problems of geophysics
• Geophysical hydrodynamics
• Hydrophysical research
• Hydrosphere physical processes modelling
• Long waves
• Mechanics of continua
• Ocean acoustics
• Ocean optics
• Remote methods in oceanology
• River flow dynamics
• Sea currents dynamics
• Sea waves dynamics
• Statistical methods in geophysics
• Stratified currents
• Theory of turbulence
• Thermal and molecular physics of sea

Chair of Physics of Atmosphere

• Atmospheric optics
• Dynamics of atmosphere
• Dynamics of mesoscaled processes in atmosphere
• Electrical fields and processes in atmosphere
• Foundation of climate theory
• Interaction between ocean and atmosphere
• Mechanics of continua
• Numerical methods in geophysics
• Optics of atmosphere
• Optics of ocean and atmosphere
• Physical foundations of Earth probing
• Physical foundations of measurements in geophysics
• Physics of atmosphere
• Physics of near-Earth space and solar-Earth
• Physics of upper atmosphere
• Remote probing of atmosphere
• Statistical methods in geophysics
• Wave and turbulent processes in atmosphere

Chair of Computer Methods in Physics

• Computational geometry
• Computational physics
• Computer image processing
• Extremal problems
• Functional analysis in normalized spaces
• Infinite-dimensional linear models
• Internet technologies
• Introduction to mathematical methods of measurements interpretation
• Mathematical models of non-linear dynamics
• Measure theory
• Method and art of mathematical modelling
• Methods of mathematical statistics
• Morphological analysis of images
• Non-numerical programming algorithms
• Pattern recognition
• Possibility: theory and applications
• Programming in JAVA
• Statistics and possibility methods of decision making
• Systemic programming
• Systems of computer-based modelling
• Theory of computer-aided measurement systems
• Theory of Hilbert spaces. Operator analysis
• Theory of quantum measurements

Division of Astronomy

Chair of Astrophysics and Stellar Astronomy

• Accretion disks
• Active galactic nuclei
• Advanced chapters of theoretical astrophysics
• Astrophysics of neutron stars and black holes
• Binary systems
• Close binary systems
• Cosmology
• Elements of stellar dynamics
• Evolution of galaxies
• Evolutionary astrophysics
• Extra-atmospheric astronomy
• Filtration of stochastic signals
• Formation of stars
• Galaxy astronomy
• General theory of relativity
• General theory of relativity and astrophysical observations
• Physics of cosmic plasma
• Physics of galaxies
• Physics of interstellar medium
• Physics of stellar atmosphere
• Practical radioastronomy
• Radiation in relativistic astrophysics
• Radioastronomy
• Solar physics and helioseismology
• Space magnetic hydrodynamics
• Spectra of accretion disks radiation
• Star clusters
• Structure and evolution of stars
• Supernovae and stellar wind in Interstellar medium
• Theoretical astrophysics
• Variable stars

Chair of Celestial Mechanics, Astrometry and Gravimetry

• Earth tides
• Ephemerical astronomy
• Global geodynamics
• Gravimetry
• Introduction to astrodynamics
• Methods of astrometry observation processing
• Observations and management of dynamical objects
• Perturbation theory
• Planets in the Universe
• Practical celestial mechanics
• Pulsar astrometry
• Radioastrometry
• Stability of Hamiltonian systems
• The problem of three bodies
• Theory of accidental functions
• Theory of the Earth's shape

Chair of Experimental Astronomy

• Astrospectropy
• Detectors of optical radiation
• Photoelectronic detectors and its application
• Practical astronomy
• Precision photometry and spectrophotometry