For foreign students
Physics and Nanotechnology

Physics and Nanotechnology

QUALIFICATION

  • First Stage of Higher Education - Bachelor of Natural Science

MODEL OF GRADUATING STUDENT

ON 1. Explain physical, chemical and mathematical methods for the study of objects, phenomena and processes for applied and basic research;
ON 2. Apply physico-chemical methods for producing nano-objects and their composites for solving applied problems, as well as methods for describing structures, structures, composition, morphologies;
ON 3. Use fundamental and modern knowledge to solve problems related to identifying the relationship between the structure and properties of macro- and micro-objects;
ON 4. Interpretation modern scientific concepts and theories within the research context in the field of physics and nanomaterials to analyze the results of scientific research;
ON 5. Identify the similarities and differences of world and Kazakhstani science in the field of innovative technology in order to create new functional nanomaterials;
ON 6. Apply modern information technologies to search, store, process and transfer the necessary new scientific and innovative form of activity for experimental and theoretical research to develop and improve methods for the synthesis of nanostructured composite materials using plasma chemical technologies;
ON 7. To practice professional skills in scientific, technical and scientific-pedagogical activities to solve problems in interdisciplinary fields of physics and nanotechnology;
ON 8. Conduct laboratory experiments, as well as analytical and numerical calculations for physical research;
ON 9. To critically evaluate modern scientific concepts and theories in the field of nanomaterials and nanotechnology to determine the object and subject of independent research;
ON 10. Select the appropriate equipment, tools and research methods in accordance with their advantages and disadvantages and apply them to solve problems in a specific subject area;
ON 11. Аpply fundamental physical laws to solve industrial, technical and everyday problems;
ON 12. To work as part of an interdisciplinary team, tolerantly perceiving ethnic, religious, social and cultural differences; to form civil and ideological positions; improve social, linguistic and physical training to ensure full compliance with the needs of the professions and society.


Program passport

Speciality Name
Physics and Nanotechnology
Speciality Code
6B05305
Faculty
of Physics and Technology

disciplines

Applied biophysics and basics of biotechnology
  • Number of credits - 9
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - Course Objectives: To establish an understanding of crucial biophysical processes in living organisms and the interconnection between physical and biological aspects of living systems as biotechnology objects. This course highlights how nanoscience offers innovative solutions for energy challenges and advances in diagnostics, therapy, and regenerative medicine. Topics Covered: Biophysical processes in organisms; physical bases of vital activity, cellular organization, membrane processes. Biochemical bases and molecular mechanisms. Main types of biotechnological processes, objects, and products. Biologically inspired nanostructures, biomaterials, and nanobiotechnology concepts.

Applied engineering calculations
  • Number of credits - 6
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - Purpose of the discipline: the formation of students' fundamental knowledge of applied engineering calculations, the ability to independent critical thinking and understanding of the current state of engineering calculations. While studying the discipline students will study the following aspects: applied mathematical issues in calculation of electrical circuits in MultiSIM and/or Electronic Workbench program, applied engineering calculations and CAD technologies, engineering calculations using AutoCAD and MathCAD programs.

Applied mathematics in physics and technology
  • Number of credits - 5
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - Course objectives: Teach mathematical methods for solving physics and engineering problems. Develop skills in numerical modeling and experimental data analysis. Topics covered: Fundamentals of vector and tensor analysis, methods for solving systems of linear algebraic equations, the role of complex numbers in applied problems, elements of probability theory and statistical analysis, engineering applications of analytic geometry, operational methods for solving differential equations (Laplace transforms), principles of calculus of variations.

Atomic physics
  • Number of credits - 6
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - Purpose: The study of the main phenomena and methods of atomic physics and the formation of physical thinking, which makes it possible to understand the patterns of the microworld. Contents: Corpuscular properties of electromagnetic waves. Microparticles wave properties. Atomic states discreteness. Quantum-mechanical description of atomic systems. Multi-electron atoms. Atom in an external field.

Basics of micro and nanoelectronics
  • Number of credits - 9
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - The purpose of the discipline: to form the knowledge on the study of advanced achievements, basic directions, trends, prospects and problems of development of modern micro and nanoelectronics; to acquire practical knowledge on the design and skills for operating industrial electronic equipment and instruments. Content: Integrated circuits. Elements of integrated circuits. Technological foundations of microelectronics. Physical properties of objects of nanometer scale; The quantum effects; Heterostructures, and Schottky barriers; Electrical properties of nanoparticles;

Chemical basics of nanotechnology
  • Number of credits - 6
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - Course objectives: Establish fundamental chemical knowledge for nanotechnology: understanding relationships between composition, structure and properties at nanoscale. This knowledge is essential for nanomaterials synthesis and applications. Topics covered: Chemical bonding (types and effects on nanoscale properties). Thermodynamics and self-assembly in nanosystems. Reaction kinetics. Chemical equilibrium. Hydrolysis and redox processes.

Computer Physics
  • Number of credits - 9
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - Course Goals: develop skills of students in writing codes, debugging and optimization of the written code; carry out basic calculations and visualization of physical processes on a computer; analyze the obtained results. Topics Covered: programming language; procedural and object-oriented programming, algorithms and accuracy; approximate methods; solving linear and non-linear equations; approximation of functions; numerical derivatives and integration, interpolation and visualisation.

Electricity and Magnetism
  • Number of credits - 9
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - The purpose of the discipline is to form an idea of electromagnetism as a theory that arose as a result of generalization of observations, practical experience and experiment within the framework of lectures, practical and laboratory classes. The discipline is aimed at studying the field of electrostatic interactions in a vacuum, the laws of the magnetic field, the law of electromagnetic induction, the system of Maxwell's equations, as well as the study of the basics of the theory of electromagnetism.

Foreign Language
  • Number of credits - 5
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - Purpose: to form the improvement of knowledge of foreign language communicative competence. The main methods of speech skills and foreign language communication skills are considered as a basis for the development of communicative competence; implementation of acquired speech skills in the process of searching, selecting and using material in English.

Higher mathematics
  • Number of credits - 6
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - Teaching students the fundamental sections of higher mathematics, the formation of logical thinking necessary in solving engineering problems. Function; domain of definition; limits; scalar and vector quantities; directional derivative; extremum of a function of several variables; conditional extremum; fundamentals of higher and linear algebra; matrix; matrix determinant; actions on a matrix; vectors; actions on vectors; complex numbers; time series; mathematical statistics and probability theory.

Information-Communication Technologies
  • Number of credits - 5
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - Рurpose: it consists in the formation of a new "digital" thinking, a critical understanding of the role and importance of modern information and communication technologies, the ability to apply information and communication technologies in various professional activities. They are being studied: the role of ICT in key sectors of society development is being studied. Architecture of computer systems. Software. Microsoft Office Internet technologies. Cloud and mobile technologies. Multimedia technologies. E-learning. Information technology in the professional field.

Kazakh (Russian) Language
  • Number of credits - 5
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - Рurpose: ensuring the qualitative assimilation of the Kazakh (Russian) language as a means of social, intercultural, professional communication through the formation of communicative competencies. The following are studied: the system of phonetic, lexical, grammatical means of language, ideas about language as a cultural phenomenon and about the specifics of speech culture; language as an element of the national linguistic picture of the world; the status of the Kazakh (Russian) language in the world space.

Mathematical Analysis
  • Number of credits - 5
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - The goal is to develop the skills to apply mathematical apparatus and mathematical methods in analysis. The discipline is aimed at studying the theory of limits; basic theorems about continuous and differentiable functions; Taylor formula; functions of several variables; series theory; improper integrals depending on parameters; multiple integrals and integrals over a surface; Fourier series and integrals.

Mechanics
  • Number of credits - 9
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - The purpose of the discipline: to present mechanics as a generalization of observations, practical experience, and experiment. Will be studied: Kinematics. Mechanical motion is the simplest form of motion of matter. Dynamics of a material point and a solid. Newton's laws. Gravitational forces. The law of universal gravitation. Forces of elasticity. Hooke's Law. Forces of friction. Inertial reference frames. The mechanical principle of relativity. Transformations of Galileo. Elements of the special theory of relativity. The postulates of Einstein. Lorentz transformations.

Military Training
  • Number of credits - 6
  • Type of control - MC
  • Description - Military Training

Module of socio-political knowledge (Sociology/ Political science/ Culture/ Psychology)
  • Number of credits - 8
  • Type of control - RK + Exam (100)
  • Description - Aim оf discipline: to develop the ability to explain and interpret subject knowledge in all fields of science, shaping of the discipline. Sociology and sociological perspectives, social structure, form of policy, organizational structure, institutions, the legal and organizational rules, content, purpose, value, policy, concept and essence of culture, semiotics of culture, psychology of personality, psychology of interpersonal communication will be studied.

Molecular physics
  • Number of credits - 6
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - Purpose: acquisition of knowledge and skills in the study of the molecular structure, properties and processes occurring in various phase states of matter. Contents: Molecular-kinetic theory fundamentals. Meaning of temperature. Thermodynamic parameters. The ideal gas state equation. Statistical distributions. Pressure in liquid and gas. Continuity equation. Bernoulli equation. Fluid flow regimes. Isoprocesses. Carnot cycle. Real gases.

Nuclear physics
  • Number of credits - 6
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - Purpose: Form the ability to describe and evaluate the general principles of nuclear physics, atomic nuclei volume processes; familiarization with the microcosm actual concepts, including the structure of the atomic nucleus and elementary particles. Contents: Atomic nuclei static properties. Radioactivity. Semiconductor, scintillation and track detectors. Nuclear fission and synthesis. Nuclear reactions. Elementary particles.

Optics
  • Number of credits - 9
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - The purpose of the discipline is to get acquainted with physical phenomena related to the laws of light propagation and its interaction with matter. The course covers the key aspects of geometric optics and the theory of the resolution of optical devices. The theory of interference phenomena is described in detail: interference of monochromatic, quasi-monochromatic and extended light sources and the theory of diffraction phenomena: Fresnel and Fraunhofer diffraction.

Philosophy
  • Number of credits - 5
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - Purpose: to form a systematic understanding of philosophy and its main problems and methods in the context of future professional activities. The main content of ontology and metaphysics is considered in the context of the historical development of philosophy; the importance of key worldview concepts in the modern world.

Physical Training
  • Number of credits - 2
  • Type of control - РК(с оценкой)
  • Description - The purpose of the discipline is the formation of social and personal competencies of students, ensuring the targeted use of the appropriate means of physical culture and sports for preservation, preparation for professional activities. As a result of studying the discipline, the graduate should know the role of physical culture in human development.

Plasma technologies and new materials
  • Number of credits - 9
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - Course Goals. Developing practical and theoretical skills in obtaining new materials based on plasma technologies and working with various methods of their control, as well as methods for processing and interpreting the results obtained. Topics Covered: Fundamentals of Plasma Physics; Physics of gas discharge processes; Plasma technologies; Methods for the synthesis of materials in a plasma environment; Methods of plasma-chemical etching of the surface of materials; Material surface functionalization methods;

Selected chapters of the theoretical physics
  • Number of credits - 9
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - Purpose of the discipline. The main sections of theoretical physics are studied to describe and explain the processes of physical processes and engineering calculations using modern methods of theoretical physics. In studying the discipline, the following aspects will be considered: Fundamentals of mathematical physics and equations mat. physics; Fundamentals of electrodynamics; Fundamentals of thermodynamics and statistical physics; Fundamentals of quantum mechanics;.

Theory of differential equations
  • Number of credits - 5
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - The goal of the discipline: to develop the ability for logical thinking and proficiency in the mathematical apparatus necessary for solving theoretical and practical problems; to solve differential and integral equations. During the course, students will develop the following abilities: - Logical thinking; - Proficiency in the mathematical apparatus necessary for solving theoretical and practical problems; - Independent study of literature on differential equations; - Mastery of methods in the theory of ordinary differential and integral equations necessary for further scientific and professional activities.

Нistory of Kazakhstan
  • Number of credits - 5
  • Type of control - [РК1+MT+РК2+ ГЭК] (100)
  • Description - The purpose of the discipline is to give objective knowledge about the main stages in the development of the history of Kazakhstan from ancient times to the present. Expected learning outcomes: 1) demonstrate knowledge and understanding of the main stages in the development of the history of Kazakhstan; 2) to correlate the phenomena and events of the historical past with the general paradigm of the world-historical development of human society through critical analysis; 3) to possess the skills of analytical and axiological analysis in the study of historical processes and phenomena of modern Kazakhstan; 4) be able to objectively and comprehensively comprehend the immanent features of the modern Kazakh model of development; 5) Systematize and give a critical assessment of historical phenomena and processes in the history of Kazakhstan. During the study of the discipline students will learn following aspects: Ancient people and the formation of a nomadic civilization, Turkic civilization and the Great Steppe, Kazakhstan in modern times (XVIII - early XX centuries), Kazakhstan as part of the Soviet administrative-command system, Kazakhstan in the world community (1991-2022).

Data for 2022-2025 years

disciplines

Abais Teaching
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - The goal of the discipline is to form in future specialists the ability to self-knowledge, the use of Abai's doctrine as the basis of spirituality and intellectuality of modern Kazakhstan, the application of their professional knowledge, understanding and abilities through the prism of humanism and education in order to strengthen the unity of the country and civil solidarity of society.The following will be studied: the concept of the teachings of Abai; sources of teaching; components of Abai's doctrine; categories of Abai's doctrine; assessment tools of the teachings of Abai; the essence and meaning of Abai’s doctrine.

Al-Farabi and Modernity
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - Aim of the discipline is to form students' ideas about the scientific and philosophical heritage of the great Turkic thinker Abu Nasr al-Farabi in developing the world and national culture. Learning outcomes: explain the main philosophical contents al-Farabi's heritage and his influence on the formation of Turkic philosophy; influence European Renaissance.

Basics of experimental methods for studying nanomaterials and nanostructures
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - Course objectives: Develop practical skills for planning experiments, preparing samples, and collecting reliable data and interpretation in nanomaterials research. Topics covered: Principles of experimental design, error analysis, and sample preparation. Safety protocols and sample handling. Scientific visualization and presentation of results. Electron and probe microscopy (SEM, AFM), X-ray diffraction analysis, Raman spectroscopy, optical microscopy, Fourier-transform infrared spectroscopy (FTIR), spectrophotometry, energy-dispersive X-ray spectroscopy (EDX).

Basics of financial literacy
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - The purpose of the discipline is to form rational financial behavior in students based on building a direct connection between understanding financial information and their practical application for making competent and informed decisions regarding personal finances and increasing their economic security, as well as the ability to critically evaluate and analyze processes related to protection their rights and interests as consumers of financial services through the use of financial instruments, including digital technologies.

Basics of methods for nanomaterial synthesis
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - The purpose of the discipline is to form students' theoretical and practical knowledge of the main methods for obtaining nanomaterials in a plasma environment Will be studied: Basic concepts and features of the synthesis of nanoparticles and nanomaterials in a plasma environment. Plasma chemical synthesis. Thermal evaporation. Plasma coating. Basic physical and chemical characteristics of nanomaterials.

Basics of micro and nanoelectronics
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - Course objectives: To provide students with a foundational understanding of integrated circuits, their fundamental elements, and the technological processes involved in microelectronics.. Topics covered: Integrated circuits (ICs) and their constituent elements. Technological foundations of microelectronics. Physical properties of nanometer-scale objects, including quantum effects. Heterostructures and Schottky barriers. Electrical properties of nanoparticles.

Deep machine learning for simulation of physical systems
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - Course Objectives: To develop competencies in applying deep learning methods for analyzing and predicting complex physical processes. The course builds practical skills in designing neural network architectures and evaluating their effectiveness in physical phenomena research. Topics covered: Fundamental theory of machine learning; Deep neural network architectures; Evolutionary algorithms for physics problems; Numerical methods for differential equations (e.g. Schrödinger equation); Extracting physical laws through image and text data analysis.

Digital measurement systems and technologies
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - The discipline aims to develop students' understanding of the basic techniques and laws in digital measurement systems and technologies, skills of critical thinking to solve technological problems using modern applications. The discipline deals with the following sections: general issues of digital measurement systems and technology, LabVIEW software environment and its applications to automated control systems, Data processing and analysis using applications.

Ecology and Human Life Safety
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - The goal of the discipline is to form a number of key competencies based on modern concepts of environmental management, implementing the principles of harmonious optimization of human interaction with nature. The following will be studied: the principles of sustainable development, conservation and reproduction of natural resources to ensure the safety of human life, methods for assessing and minimizing risks, protecting against dangers, including during travel, measures to eliminate the consequences of accidents, anthropogenic disasters, natural disasters, environmental protection and rational environmental management.

Ecology and Sustainable Development
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - The discipline is aimed at fostering students' environmental worldview, developing a scientific understanding of the interrelationship between nature and society, and providing comprehensive knowledge of the goals and principles of sustainable development. The course addresses global and regional environmental issues, environmental protection, and approaches to the rational use of natural resources. Students acquire the skills to make scientifically grounded and responsible decisions in the field of sustainable development.

Electronics and Circuit Design for Physical Systems
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - Course Objectives: To provide students with a fundamental understanding of electronic components, circuit analysis techniques, and design principles, with a particular emphasis on the operation, characteristics, and application of semiconductor devices in sensing, control, and measurement within physical systems. Topics Covered: Basic circuit analysis (DC/AC), passive components, semiconductor physics fundamentals, diodes (rectifiers, LEDs), transistors (BJT, MOSFET) as switches and amplifiers, operational amplifiers (Op-Amps), digital logic gates, and introduction to sensors and data acquisition interfaces for physical parameters.

Entrepreneurship
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - The discipline is aimed at developing students’ economic thinking and enhancing their entrepreneurial competencies. The course covers the fundamental principles of the market economy and the basics of organizing entrepreneurial activity. Students study the mechanisms of economic functioning, the role of business in socio-economic development, and the stages of business creation and management.

Fundamentals of human life safety
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - Тhe discipline is aimed at preparing students who know the theoretical and practical foundations of ensuring human safety from dangerous, harmful environmental factors, rules of conduct in emergency situations and obtaining practical skills in providing first aid to victims.

Fundamentals of Radio Electronics
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - Course Goals: to provide basic training in electrical engineering and electronics, necessary for the operation of existing and development of new efficient electrical and electronic systems. Topics Covered: Ideal elements; Vector diagrams; Resistors; Capacitors; Diodes; Transistors; Microcircuits; Elements of optoelectronics; Decoders; Encryptors; Multiplexers; Demultiplexers; Digital comparators; Adders; Triggers; Registers;

General electrical and electronic engineering
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - The purpose of the discipline: to form student’s skills in the analysis and application of methods of calculation of electrical circuits, elements of electrical circuits, and basic knowledge of digital electronics. The discipline will cover the following sections: theoretical foundations of electrical engineering, the basics of industrial and digital electronics, high voltage technology.

Intelligent Analysis and Processing of Experimental Data
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - Course objectives: Develop practical skills in processing, analyzing, and interpreting experimental data using modern statistical and AI-based methods. Emphasis is on transforming raw measurements into meaningful scientific insights in nanoscience. Topics covered: Data cleaning, noise reduction, and feature extraction. Statistical distributions, regression, and hypothesis testing. Clustering and dimensionality reduction. Application of AI/ML techniques (e.g., classification, pattern recognition). Visualization and reporting of scientific data.

Intelligent control systems of physical devices and technological processes
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - The discipline focuses on teaching students the basic elements of intelligent control systems of physical devices and technological processes in the creation and operation of automatic and automated control systems. The discipline considers the following sections: The principle of operation of sensors and their features, The basic concept of actuators, Interfaces of connection of sensors and actuators, Elements of the Internet of things and its application in intelligent control systems of physical devices and technological processes.

Introduction to inclusion
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - The purpose of the discipline: to master the system of scientific and theoretical knowledge of the basics of inclusive education, the formation of value orientations for organizing interaction with people with special educational needs, and mastering competencies in the field of professional activity in an inclusive environment.

Introduction to the modern solid state physics
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - The purpose of the discipline is to create a fundamental knowledge base based on the classical and quantum theory of solids, on the basis of which in the future it will be possible to more thoroughly and in detail study the sections of physics as part of a cycle of courses on nanoengineering. The training course forms an in-depth understanding of the influence of crystalline and electronic structures on the basic physical processes and phenomena occurring in solids. The discipline is aimed at studying: the structure of the crystalline structure, the main types of bonds, lattice dynamics, electrical, magnetic, elastic, optical, thermal and mechanical properties of solid state materials

Legal Bases of Corruption Control
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - The purpose of the discipline To develop the ability to analyze the activities of government authorities, political and public organizations in the field of anti-corruption. To provide objective knowledge about the problems of corruption in modern society. To demonstrate the role of artificial intelligence (AI) in identifying, preventing, and analyzing corruption risks. To explain the main provisions of anti-corruption legislation. To teach practical skills for combating corruption using modern digital technologies and AI-based analytical tools.

Management and Commercialization in Nanotechnology
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - Course objectives: To equip students with essential knowledge and skills in managing and commercializing nanotechnology-based innovations. Topics covered: Fundamentals of innovation management, intellectual property (IP) strategies, technology transfer, licensing. Venture creation and startup development. Funding and investment strategies, market analysis, commercialization pathways. Regulatory and ethical considerations.

Methods for Solving Inverse Problems and Building Digital Twins in Physics
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - Course objectives: To equip students with knowledge and skills in solving inverse problems in physical systems and developing digital twins for modeling and predicting complex phenomena. Topics covered: Introduction to inverse problems in physics: formulation, ill-posedness, regularization; Methods for solving inverse problems: least squares method, numerical methods; Practicum on building a digital twin of a nanomaterial or process. Creating a digital twin of a nanostructure: from modeling to verification; thermal conductivity of thin films, optics of nanoparticles, properties of nanocomposites.

Methods of controlling and analyzing materials
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - Course Goals. Development of practical and theoretical skills in working with various methods of analysis and control of materials, as well as methods for processing and interpreting the results obtained. Topics Covered: Occupational health and safety at work and in the laboratory. The main types of non-destructive testing in industry. Methods of control and analysis of materials. Features of microscopic control methods. Ellipsometry. Rules for certification and standardization of laboratories and equipment.

Microcontrollers and Digital Measurements in Physics
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - Course objectives: Teach microcontroller systems using Arduino platform for sensor integration and digital measurements. Develop skills in data acquisition, processing and analysis for physics experiments. Topics covered: Microcontroller basics, Arduino programming, sensor interfacing (temperature, light, motion), data logging, signal processing, communication protocols (I2C, SPI).

Modeling of high-tech systems
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - Course Objectives: To equip students with fundamental knowledge and practical skills in developing, analyzing, and interpreting models of diverse high-tech systems using modern simulation tools. Topics Covered: Classification of models, stages and principles of mathematical modeling. Methods for studying systems, including simulation modeling. Emphasis on technical and software simulation tools, with hands-on application using COMSOL Multiphysics for cases in physics, engineering, and nanotechnology.

Modern Computational Environments and AI Tools in Physics
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - Course objectives: To introduce students to modern computational environments (e.g., Wolfram Mathematica, MATLAB) and artificial intelligence tools. Students will learn to model physical processes, analyze data using AI methods, and visualize scientific results, thereby enhancing analytical thinking and research skills. Topics covered: Fundamentals of selected platforms (interface, syntax, data types); solving physical equations; using AI tools (e.g., regression, classification, neural networks); numerical simulation; scientific data processing; and visual representation.

Modern power plants and fundamentals of vacuum technology
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - Goal: To form the practical connection between student's theoretical knowledge of the high-temperature thermonuclear plasma properties and practical methods of its creation and technical use in controlled nuclear fusion devices. Content: fundamentals of vacuum physics; vacuum classification; vacuum measurement methods; principles of gas flow measurement; processes of absorption and desorption; thermonuclear fusion plants; inertial thermonuclear fusion;

Nanophotonics and Optoelectronics
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - Course Objectives: To provide students with a comprehensive understanding of fundamental principles of light-matter interaction at the nanoscale, and the design/operation of nanophotonic and optoelectronic devices. The course aims to equip students with the knowledge to analyze and engineer optical phenomena in nanostructures. Topics Covered: Fundamentals of classical and quantum optics, dielectric nanostructures, photonic crystals, plasmonics, metamaterials. Quantum emitters, single-photon sources, nanoscale lasers, LEDs, photodetectors, solar cells. Integrated nanophotonic circuits and optical sensing applications.

Nanotechnologies and Nanomaterials in Energy and Biomedicine
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - Course objectives: Provide students with knowledge about fundamental properties and applications of nanomaterials in energy and medical fields. The course examines nanotechnology solutions for contemporary challenges in diagnostics, therapy and energy storage. Topics covered: Physicochemical properties of functional nanomaterials, their interactions with biological systems, medical diagnostic tools, next-generation energy storage systems (nano-batteries, hydrogen technologies).

Nanotechnologies and nanomaterials in thermonuclear power industry and biomedicine
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - Course Goals: to form the systematized knowledge on the application of nanotechnologies and functional nanomaterials in energetics, biology and medicine. Topics Covered: interaction of nanoparticles with biological objects; advantages of using nanoproducts in diagnostics, pharmacology and medicine; functional nanomaterials; Application of nanotechnology in production, transportation and storage of energy; nano-capacitors and nano-accumulators; Fuel cells and hydrogen energy.

Numerical Methods and Algorithms for Physical Data Analysis
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - Course objectives: Teach numerical methods implementation in Python from scratch for solving physics problems and data analysis. Focuses on algorithm theory and practical coding. Topics covered: Numerical differentiation/integration. Root-finding (bisection, Newton-Raphson). ODE solving (Euler, Runge-Kutta). Numerical linear algebra. Error analysis. Statistical methods (curve fitting, hypothesis testing). All methods implemented in Python.

Optical Spectroscopy and Analysis of Nanomaterials
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - Course objectives: To provide students with a comprehensive understanding of the principles and applications of various optical spectroscopic techniques for the analysis and characterization of nanomaterials. Topics covered: Fundamentals of light-matter interaction at the nanoscale. Principles and applications of UV-Vis absorption and photoluminescence spectroscopy, Raman spectroscopy, Fourier Transform Infrared (FTIR) spectroscopy, and ellipsometry. Focus on using these techniques to analyze the electronic, vibrational, and structural properties of diverse nanomaterials (e.g., quantum dots, nanowires, 2D materials, plasmonic nanoparticles).

Physical basics of instrumentation
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - Course goals: to form students' systematic knowledge of the laws of physics underlying the operation of instruments and installations. Develop skills in the design, construction and operation of devices. Content: engineering design and construction of devices; Material, mechanical, electromagnetic and optical foundations of devices. Sensors.

Physics of Heterostructures, and Thin Films
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - Course Objectives: To provide students with a comprehensive understanding of the physical principles governing the growth, properties, and applications of heterostructures and thin films. The course aims to enable analysis of electronic, optical, and structural characteristics of these systems and understanding their relevance in modern devices. Topics Covered: Fundamentals of crystal growth, thin film deposition methods, their thermodynamics and kinetics. Structural characterization, electronic and optical properties. Quantum wells and superlattices. Applications in optoelectronics, photovoltaics, and advanced electronics.

Physics of Quantum Materials and Nanostructures
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - Course Objectives: Equip students with an understanding of the physical principles behind quantum materials and nanoscale structures where electron interactions and topology play key roles. Emphasizes unique phenomena in low-dimensional systems and their potential in next-generation quantum and electronic technologies. Topics Covered: Quantum confinement effects in 0D, 1D, and 2D systems. Topological materials (topological insulators, Dirac and Weyl semimetals). Strongly correlated materials and Mott insulators. Magnetism and unconventional superconductivity. Quantum dots, nanowires, and 2D materials (e.g., graphene, TMDCs). Applications in quantum information, spintronics, and nanoscale devices.

Plasma Technologies for Material Modification
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - Course objectives: Provide students with a comprehensive understanding of the principles, mechanisms, and applications of plasma-based technologies for modifying material surfaces. Topics covered: Fundamentals of plasma generation (cold/thermal). Plasma-surface interaction mechanisms (etching, deposition, activation, cleaning). Specific plasma surface modification processes (plasma etching, PECVD, polymerization, sputtering, ion implantation). Characterization techniques for modified surfaces and industrial applications.

Scientific Research Methods
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - Рurpose: to form a methodological and scientific culture, a system of knowledge, skills and abilities in the organization and conduct of scientific research. General scientific research methods are studied, including methods of searching, processing, systematization, analysis, synthesis, generalization and argumentation of scientific information to obtain the objective content of scientific knowledge.

Simulation of physical processes
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - Course Goals: the formation of programming skills of the basic mathematical algorithms used in the simulation of physical phenomena Topics Covered: the main computational methods used in solving physical problems and in processing experimental data. The method of molecular dynamics. The least square method and regression analysis. Information models and computer experiments in physics. Automate a physical experiment.

Data for 2022-2025 years

INTERNSHIPS

Academic
  • Type of control - Защита практики
  • Description - The purpose of the internship is consolidation of the received theoretical knowledge, professional orientation of students; familiarization and study of the organization of activity, structure, directions of scientific activity of the department, faculty, university. Will be studied: consultation of the head of internship from the department; familiarization with the scientific directions of the department, the structure of the faculty and the university

Industrial
  • Type of control - Защита практики
  • Description - The purpose of the internship is to form professional knowledge in the field of the chosen specialty, to consolidate the theoretical knowledge obtained in the disciplines of the directions and special disciplines of the program, to master the necessary professional competencies in the chosen direction of specialized training. The internship is designed to create conditions for the formation of practical competencies

Pre-Diploma
  • Type of control - Защита практики
  • Description - TThe objective is form the ability to consolidate the theoretical knowledge, analytical and managerial skills, collecting material for the diploma work. The following will be studied: analysis of enterprises' performance effectiveness, advantages and disadvantages of enterprises, list of partners, agreements, contracts, arrangement of meetings, negotiations, recruitment of personnel, team work.

Pre-Graduation
  • Type of control - Защита практики
  • Description - The purpose of the internship is deepening and consolidation of theoretical knowledge gained in the process of learning, the selection and systematization of material for the thesis; writing a thesis; preliminary defense of the thesis.

Production
  • Type of control - Защита практики
  • Description - The purpose of the practice is to form professional knowledge in the field of the chosen specialty, to consolidate the theoretical knowledge obtained in the disciplines of the directions and special disciplines of the program, to master the necessary professional competencies in the chosen direction of specialized training. The practice is designed to create conditions for the formation of practical competencies.

Professional (educational)
  • Type of control - Защита практики
  • Description - The purpose of the practice is to form the ability to apply in the field in practice their knowledge and skills formed during the development of the discipline "Geodesy", as close as possible to the production conditions of land management. As a result of the internship the student will be able to: 1. use surveying tools; 2. make verification of theodolites, levels, total stations and their installation in the working position; 3. lay theodolite course; 4. make leveling; 5. perform total station survey; 6. to produce laboratory processing of field measurements; 7. make a plan, longitudinal and transverse profiles and other necessary drawings. The practice of geodesy refers to a cycle of training practices. During the practice, the following types of geodetic works will be done: verification of theodolites, levels, total stations and their installation in the working position: centering, horizonting; measurements by theodolite, level, total station; laying of the traverse along the boundary of land use and checking the admissibility of measurement errors; in excess of measurement errors, repeated measurements are made; leveling and checking the admissibility of measurement errors; surveying and manufacturing plan.

Data for 2022-2025 years