PhD program
Technical physics (KTU)

Technical physics (KTU)

MODEL OF GRADUATING STUDENT

Program passport

Speciality Name
Technical physics (KTU)
Speciality Code
8D05304
Faculty
of Physics and Technology

disciplines

Academic writing
  • Number of credits - 2
  • Type of control - [RK1+MT1+RK2+Exam] (100)
  • Description - Formation of doctoral students' management skills in research activity due to the development of the technique of presenting the obtained fundamental and applied results in the relevant profile field through scientific analysis and modern information and communication technologies in the form of various scientific and technical written works in accordance with the requirements of leading peer-reviewed international publications having non-zero impact factor included in the Clarivate Analytics (Web of Science Core Collection) and Scopus databases. As a result of studying the discipline, the doctoral candidate will be able to: 1. determine the main structural elements of a scientific article by their functions, correctly draw up a bibliographic list in a scientific work, citation and links to used literature specially selected on the research topic, using library catalogs, reference books, electronic databases in the worldwide information network; 2. formulate the goals and objectives of the study on the basis of rethinking the accumulated scientific and professional experience, using the scientific style of presentation, building the logical structure of your own scientific text and operating with the basic logical methods of analysis through recognition and delimitation of the author's position on various issues; 3. correctly state the results of research activities, observing the principles of academic ethics defined by copyright, and applying the principles of constructing successful arguments and the conditions for their use with a deep understanding of personal responsibility for the reliability of the results of their scientific work; 4. use the methodological foundations of scientific research, the apparatus and algorithms for analyzing the innovative development of science and technology, the methodology for assessing the most important statistical indicators and scientific and technical processes, the comparative analysis of phenomena and innovative strategies in the examination of technical documentation needed to prepare reports and generate applications for innovative projects with subsequent drawing up technical specifications and specifications; 5. develop the practical recommendations on the implementation of the results of research activities in the educational process and production based on the implementation of methodological justification and assessment of the effectiveness of scientific activity depending on the requirements for product quality, costs and production needs. Fundamentals of the methodology and methods of scientific work. Planning and determining the structure of a scientific article. Preparation and publication of articles in peer-reviewed journals. Requirements of the editorial commission of the journal for publication by profile. Definition of the topic, selection of sources, grouping of the bibliography. Analysis and synthesis of literature on the topic. Composition and auxiliary scientific apparatus of publication. Academism of exposition. Title, keywords, resume. Mandatory references and footnotes to the works of predecessors and colleagues. Citation. The basic rules of conduct in oral dispute and in written debate. The logic of evidence. Notices, reviews and critical reviews. Self-criticism, recognition of mistakes. Plagiarism and the fight against this negative phenomenon. The list of scientific publications recommended for the publication of the main results of scientific activity. «Scopus» database. «Web of Knowledge» database. Using databases for literary search. Performance indicators of publications. Author’s citation index (Hirsch index). Impact factor of Journal Citation Reports (JCR) by the Web of Science database. SCIMago Journal Rank (SJR) percentile by the Scopus database (CiteScore).

Computer modeling of engineering problems
  • Number of credits - 5
  • Type of control - [RK1+MT1+RK2+Exam] (100)
  • Description - The purpose of the discipline: the formation of in-depth skills in computer technology methods for constructing static and dynamic models when analyzing and processing the results of the considered scientific, technical, fundamental and applied problems As a result of studying the discipline, the doctoral candidate will be able to: 1. carry out physical and technical research using standard and specially designed tools, software and application packages; 2. analyze the model to optimize the parameters of the studied object in the field of its professional activity and include new functions or change the modeling modes, including those for the modified environment. 3. use modeling methods to describe the patterns of technological processes and their optimization; 4. substantiate the usefulness and decision-making, the selection and description of the criteria of adequacy, stability, efficiency and identification of the model of the object when conducting computational experiments 5. apply the methods of mathematical analysis and computer modeling to formulate and solve problems related to the development, implementation and commercialization of new high technology. Mathematical model. Classification of models. The main stages of mathematical modeling. Tasks of simulation. Construction of static and dynamic models using modern software. Scopes of models. Stages of building models. Advantages and disadvantages of simulation. Experiments with physical models. Investigation of the processes of burning energy fuel in order to produce energy and heat. Mathematical / numerical models. Mathematical model of turbulent heat and mass transfer. The equation of continuity and the law of conservation of momentum. Energy equation. The equation for the component. Reynolds averaging. A group of k-ε turbulence models. Monte-Carlo Method. Differential approximation.

Elective Chapters of Condensed Matter Physics
  • Number of credits - 5
  • Type of control - [RK1+MT1+RK2+Exam] (100)
  • Description - The aim of the discipline is studying the properties of solids, the physical properties of micro- and nanostructures, their energy spectrum; electrical, mechanical, magnetic and optical properties of nanostructures, features of their application; models of oscillations in the lattice, the interaction of particles and quasiparticles with defects; materials used in organic optoelectronics; applications of organic optoelectronic devices, carbon nanostructures, their classification and physical properties. As a result of studying the discipline, the doctoral candidate will be able to: 1. evaluate the mechanical, electrical and optical properties of the condensed matter; defects in crystalline solid states, their influence on the properties of the parameters of the crystal lattice, defects caused by energy states; 2. use semiconductor and metal quantum structures, experimental methods and techniques for obtaining and researching new materials and nanomaterials; 3. explain the principles of operation of an organic optoelectronic device, the chemical and physical properties of organic semiconductors and other electroactive materials; 4. use modern information and communication technologies for modeling; 5. possess standard digital methods in the programming environment, methods of approximation and interpolation, methods of construction, optimization, tuning algorithms and programs. Crystalline and non-crystalline materials. Defects in the crystals. Electrons in crystals. Electrical properties of materials. Lattice vibrations. Photoelectric and optical phenomena. Organic optoelectronics. Polymeric organic semiconductors. Organic matter luminescence. Organic nanostructured materials. Carbon structures. Amorphous semiconductors.

Emission Phenomena in Surface Analysis Methods
  • Number of credits - 5
  • Type of control - [RK1+MT1+RK2+Exam] (100)
  • Description - The aim of the discipline is studying the properties of solids, the physical properties of micro- and nanostructures, their energy spectrum; electrical, mechanical, magnetic and optical properties of nanostructures, features of their application; models of oscillations in the lattice, the interaction of particles and quasiparticles with defects; materials used in organic optoelectronics; applications of organic optoelectronic devices, carbon nanostructures, their classification and physical properties. As a result of studying the discipline, the doctoral candidate will be able to: 1. evaluate the mechanical, electrical and optical properties of the condensed matter; defects in crystalline solid states, their influence on the properties of the parameters of the crystal lattice, defects caused by energy states; 2. use semiconductor and metal quantum structures, experimental methods and techniques for obtaining and researching new materials and nanomaterials; 3. explain the principles of operation of an organic optoelectronic device, the chemical and physical properties of organic semiconductors and other electroactive materials; 4. use modern information and communication technologies for modeling; 5. possess standard digital methods in the programming environment, methods of approximation and interpolation, methods of construction, optimization, tuning algorithms and programs. Classification of surface analysis methods. Ion beam spectroscopies. Backscattering spectroscopies. Interaction of electron beam with solids, Auger electron spectroscopy. X-ray photoelectron spectroscopy. Scanning electrron microscopy. Scanning tunneling microscopy Atomic force microscopy. X-ray diffraction.

PhD thesis writing and defence
  • Number of credits - 12
  • Type of control - Докторская диссертация
  • Description - The main purpose of "PhD thesis writing and defence": of a doctoral dissertation is the formation of the doctoral students' ability to disclose the content of research work for the defense of the thesis. During the study of course, doctoral student's should be competent in: 1. to substantiate the content of new scientifically grounded theoretical and experimental results that allow to solve a theoretical or applied problem or are a major achievement in the development of specific scientific directions; 2. explain the assessment of the completeness of the solutions to the tasks assigned, according to the specifics of the professional sphere of activity; 3. they can analyze alternative solutions for solving research and practical problems and assess the prospects for implementing these options; 4. apply the skills of writing scientific texts and presenting them in the form of scientific publications and presentations. 5. to plan and structure the scientific search, clearly highlight the research problem, develop a plan / program and methods for its study, formalize, in accordance with the requirements of the State Educational Establishment, the scientific and qualification work in the form of a thesis for a scientific degree Doctor of Doctor of Philosophy (PhD) on specialty «8D07502 – Standardization and certification (by industry)». During the study of the discipline doctoral student will learn following aspects: Registration of documents for presentation of the thesis for defense. Information card of the dissertation and registration-registration card (in the format Visio 2003). Extract from the minutes of the meeting of the institution, in which the preliminary defense of the thesis took place. Cover letter to the Higher Attestation Commission. Expert conclusion on the possibility of publishing the author's abstract. Expert opinion on the possibility of publishing a dissertation. Minutes of the meeting of the counting commission. Bulletin for voting. A shorthand record of the meeting of the dissertational council. List of scientific papers. Response of the official opponent. A review of the leading organization. The recall of the scientific adviser.

Scientific Research methods
  • Number of credits - 3
  • Type of control - [RK1+MT1+RK2+Exam] (100)
  • Description - The purpose of studying the discipline: formation of knowledge about the principles, basic concepts and laws, as well as terminology, content and specific features of the organization, and management of scientific research in technical physics in the chosen field of training. As a result of studying the discipline, the doctoral candidate will be able to: 1. analyze and evaluate modern scientific achievements in the field of thermophysics, cryotechnology, energy; 2. own the methodology of theoretical and experimental research, taking into account the characteristics of the selected field; 3. use modern information and communication technologies and modern databases (Clarivate Analytics, Scopus, RSCI, etc.); 4. to make analytical reviews on scientific and technical problems; 5. generate new ideas in solving research and practical problems, including in interdisciplinary fields. The main technologies, operations, practical methods and techniques for conducting scientific research based on the modern achievements of domestic and foreign scientists in the field of 3D modeling of heat and mass transfer during fuel combustion. Technologies for optimizing energy processes; processes occurring in cryogenic plants. Diffusion instability. Renewable energy sources. Justification of the topic of scientific research. Scientific research, analysis, experiment, data processing, obtaining sound effective solutions using information technologies and modern databases, such as Clarivate Analytics, Scopus, RSCI and others. Methodology and methods of scientific research, as well as how to organize those when conducting research in the field of thermal physics, cryophysics and energy. The purpose and objectives of the study, the planning and conduct of the experiment, the processing of measurement results, comparing the results of the experiment with theoretical models. Conclusions of scientific research. Preparation of a report, articles on the results of scientific research that meet all the requirements of journals included in the Web of science and Scopus databases.

Thermodynamics, statistical physics and physical kinetics
  • Number of credits - 5
  • Type of control - [RK1+MT1+RK2+Exam] (100)
  • Description - Doctoral students study the basic principles of the thermodynamic approach to the phenomenological description of physical processes in macroscopic systems and statistical methods for modeling the equilibrium and nonequilibrium behavior of many-particle classical and quantum systems. Acquaintance with the basic laws of thermodynamics, types of statistical distributions and the conditions of their applicability, basic equations of physical kinetics. The application of statistical methods for describing the properties of ideal systems to the description of various types of quasiparticles and elementary excitations in the physics of a condensed state. In the course of studying the course to form the ability of doctoral students: 1. formulate and prove the main results of thermodynamics and statistical physics; 2. to analyze the physical situation in thermodynamic systems; 3. apply the laws of thermodynamics to understand the physical processes in the microworld and the macroworld; 4. be able to get the Fokker-Planck equation, know the range of applicability of this kinetic equation, know the examples of using the Fokker-Planck equation to describe various physical systems; 5. competently use in its activities the physical content and conceptual apparatus of thermodynamics, statistical physics and physical kinetics. Basic principles of classical and quantum statistics. Thermodynamic quantities. Laws of thermodynamics of equilibrium systems. Conditions of balance and stability. Phase transitions. General methods of equilibrium statistical mechanics. Application of methods of quantum and statistical theory in condensed state physics. The theory of fluctuations and Brownian motion.

Data for 2017-2020 years

disciplines

Computer modeling of engineering problems
  • Type of control - [RK1+MT1+RK2+Exam] (100)
  • Description - The purpose of the discipline: the formation of in-depth skills in computer technology methods for constructing static and dynamic models when analyzing and processing the results of the considered scientific, technical, fundamental and applied problems As a result of studying the discipline, the doctoral candidate will be able to: 1. carry out physical and technical research using standard and specially designed tools, software and application packages; 2. analyze the model to optimize the parameters of the studied object in the field of its professional activity and include new functions or change the modeling modes, including those for the modified environment; 3. use modeling methods to describe the patterns of technological processes and their optimization; 4. substantiate the usefulness and decision-making, the selection and description of the criteria of adequacy, stability, efficiency and identification of the model of the object when conducting computational experiments; 5. apply the methods of mathematical analysis and computer modeling to formulate and solve problems related to the development, implementation and commercialization of new high technology. When studying the discipline, doctoral students will study the following aspects: Mathematical model. Classification of models. The main stages of mathematical modeling. Tasks of simulation. Construction of static and dynamic models using modern software. Scopes of models. Stages of building models. Advantages and disadvantages of simulation. Experiments with physical models. Investigation of the processes of burning energy fuel in order to produce energy and heat. Mathematical / numerical models. Mathematical model of turbulent heat and mass transfer. The equation of continuity and the law of conservation of momentum. Energy equation. The equation for the component. Reynolds averaging. A group of k-ε turbulence models. Monte-Carlo Method. Differential approximation.

Elective Chapters of Condensed Matter Physics
  • Type of control - [RK1+MT1+RK2+Exam] (100)
  • Description - The aim of the discipline is studying the properties of solids, the physical properties of micro- and nanostructures, their energy spectrum; electrical, mechanical, magnetic and optical properties of nanostructures, features of their application; models of oscillations in the lattice, the interaction of particles and quasiparticles with defects; materials used in organic optoelectronics; applications of organic optoelectronic devices, carbon nanostructures, their classification and physical properties As a result of studying the discipline, the doctoral candidate will be able to: 1. evaluate the mechanical, electrical and optical properties of the condensed matter; defects in crystalline solid states, their influence on the properties of the parameters of the crystal lattice, defects caused by energy states; 2. use semiconductor and metal quantum structures, experimental methods and techniques for obtaining and researching new materials and nanomaterials; 3. explain the principles of operation of an organic optoelectronic device, the chemical and physical properties of organic semiconductors and other electroactive materials. 4. use modern information and communication technologies for modeling. 5. possess standard digital methods in the programming environment, methods of approximation and interpolation, methods of construction, optimization, tuning algorithms and programs Crystalline and non-crystalline materials. Defects in the crystals. Electrons in crystals. Electrical properties of materials. Lattice vibrations. Photoelectric and optical phenomena. Organic optoelectronics. Polymeric organic semiconductors. Organic matter luminescence. Organic nanostructured materials. Carbon structures. Amorphous semiconductors

Emission Phenomena in Surface Analysis Methods
  • Type of control - [RK1+MT1+RK2+Exam] (100)
  • Description - The aim of the discipline is to acquire knowledge thorough understanding of physical principles of radiation interaction with solids employed in the techniques of surface analysis methods used in solid state physics and technology, features of the instrumentation of the techniques. As a result of studying the discipline, the doctoral candidate will be able to: 1. Ability to choose the appropriate surface analysis methods taking in account field of applications and existing limitations 2. Acquired knowledge on regularities of photon, ion, electron interaction employed in surface analysis methods 3. Ability to apply electron spectroscopies and methods in chemical and morphology analysis of solids. 4. Ability to apply ion based spectroscopies in surface composition analysis of solids 5. Ability to use x-ray based spectroscopies in structural and composition analysis Classification of surface analysis methods. Ion beam spectroscopies. Backscattering spectroscopies. Interaction of electron beam with solids, Auger electron spectroscopy. X-ray photoelectron spectroscopy. Scanning electrron microscopy. Scanning tunneling microscopy Atomic force microscopy. X-ray diffraction

Mathematical Basics for Engineering Experiment Theory
  • Type of control - [RK1+MT1+RK2+Exam] (100)
  • Description - The aim of the discipline is to master statistical methods for the processing of experiment results, methods for fitting empirical functions to experimental data, methods for experimental design, to master methods of the statistical hypothesis testing, to acquire skills of mathematical modeling. As a result of studying the discipline, the doctoral candidate will be able to: 1. Are able to plan experiments, taking into account the properties, merits and flaws of the chosen plan; 2. Are able to construct a mathematical model of the process investigated and to statistically evaluate the adequacy of that model; 3. Are able to statistically process data obtained from experiments and to approximate them by empirical functions; 4. Are able to draw statistically sound conclusions and to verify statistical hypotheses; 5. Are able to apply a priori modeling methods for the analysis of initial information. Statistical methods for experiment data processing. Point type parameter ratings. Interval type parameter ratings. Types of distribution functions. Checking hypothesis. Elements of variance analysis. Method of the least squares and its application. Approximation of experiment data by empiric functions. Approximation of experiment data by one variables empirical functions. Approximation of experiment data by two variables empirical functions. Calculation of coefficients of regression equation. Formulas of an evaluation of factors of the regression equation. Examples of an evaluation of factors of the regression equation. Statistical analysis of regression equations. Investigation of model adequateness. Complete correlation matrix and its properties. Plans of the first order. Total factorial experiments. Fractional replicas and their phenomena. Resolving power of fractional retorts. Solution of examples. Plans of the second order. Orthogonal central compositive plans. Examples of application of orthogonal central compositive plans. Rototable plans. Examples of application of rototable plans. Methods of random balance. Apriori modelling. Compromise problems.

Data for 2017-2020 years

INTERNSHIPS

Participation in international scientific conferences
  • Type of control - Защита НИР
  • Description - The main purpose of "Participation in international scientific conferences": is the formation of doctoral 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, doctoral 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. During the study of the discipline doctoral student will learn following aspects: Analysis of the rating of scientific and international conferences. Scientific conferences on types of participation. International and local conferences. Publication of a scientific article in accordance with the requirements of editorial boards.

Performance Doctor
  • Type of control - Защита НИР
  • Description - The main purpose of "The implementation of a Doctoral Thesis": the formation of doctoral students in preparation for the defense of the thesis for the Ph.D. in specialty (by industry). During the study of course, doctoral student's should be competent in: 1. demonstrate the progress of solving problems arising in the course of research activities and requiring in-depth 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. During the study of the discipline doctoral student will learn following aspects: Presentation and preliminary examination of the thesis. Registration of the applicant's case in the Academic Council of the University. Announcement of thesis defense. Publication and dispatch of the author's abstract. Registration of documents after the defense of the thesis.

Publication in journals recommended by CCSES or indexed by Web of Science, Scopus Databases
  • Type of control - Защита НИР
  • Description - The main purpose of "Publication in journals recommended by CCSES or indexed by Web of Science, Scopus Databases": is the formation of doctoral students' skills in presenting the results of research and publication in periodicals recommended by CCSON or included in the Thomson Reuters, Scopus databases. During the study of course, doctoral student's should be competent in: 1. is able to substantiate the main requirements for an article for publication in the editorial office of the journal and the definition of the impact factor index in periodicals recommended by CCSON or included in the Thomson Reuters, Scopus databases; 2. publish their author's article in periodicals recommended by CCSON or included in the Thomson Reuters, Scopus databases; 3. can use a technical foreign language to publish an article; 4. analyze the developed and experimental data of foreign scientists according to the selected topic; 5. they are able to evaluate the results and the given methodology for solving the problems posed, using the experimental data of the investigated region. During the study of the discipline doctoral student will learn following aspects: Carry out a thorough analysis of the impact factor of periodicals recommended by CCSON or included in the Thomson Reuters, Scopus databases. The choice of the current topic and the indication of scientific novelty. Conducting a comparative analysis of their results with the world. Literate translation of the article. Writing and sending an article. Reviewing the article.

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 doctoral 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, doctoral 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. During the study of the discipline doctoral student will learn following aspects: Analysis of the rating of scientific and international conferences. Scientific conferences on types of participation. International and local conferences. Publication of a scientific article in accordance with the requirements of editorial boards.

Publication of the main scientific results of the dissertation in scientific journals
  • Type of control - Защита НИР
  • Description - The main purpose of " Publication of the main scientific results of the dissertation in scientific journals": is the formation of doctoral students' skills in presenting the results of research and publication in periodicals recommended by CCSON or included in the Thomson Reuters, Scopus databases. During the study of course, doctoral student's should be competent in: 1. is able to substantiate the main requirements for an article for publication in the editorial office of the journal and the definition of the impact factor index in periodicals recommended by CCSON or included in the Thomson Reuters, Scopus databases; 2. publish their author's article in periodicals recommended by CCSON or included in the Thomson Reuters, Scopus databases; 3. can use a technical foreign language to publish an article; 4. analyze the developed and experimental data of foreign scientists according to the selected topic; 5. they are able to evaluate the results and the given methodology for solving the problems posed, using the experimental data of the investigated region. During the study of the discipline doctoral student will learn following aspects: Carry out a thorough analysis of the impact factor of periodicals recommended by CCSON or included in the Thomson Reuters, Scopus databases. The choice of the current topic and the indication of scientific novelty. Conducting a comparative analysis of their results with the world. Literate translation of the article. Writing and sending an article. Reviewing the article.

Research practice
  • Type of control - Защита практики
  • Description - Рurpose of practice: to develop the ability of theoretical generalization and practical research of data for creation of an original research portfolio of scientific work based on methods of planning, organization of research activities, application of scientific methods of studying objects and analytical system of their forecasting. During the study of practice, doctoral students should be competent in: - critically evaluating the scientific literature on the subject of scientific research in the field of fundamental and applied marketing; - formulating actual scientific problems, directions, hypotheses of research, including interdisciplinary ones, within the framework of own scientific-experimental and managerial activities; - plan and organize research activities: collection, processing and analysis of the main technical and economic, financial, marketing, statistical and empirical data, using a modern analytical system to develop strategic and forecast solutions for the development of the research object; - evaluate the validity of methods used in scientific research on marketing issues; - carry out scientific experiments to study the market potential, competitive advantages, consumer behavior, innovative development and correctly analyze their results; - creating research products both independently and as a part of research teams on the basis of observance of scientific ethics, correlating own scientific interests with public needs; - broadcasting their own results of research in the field of marketing to a wide range of specialists in the relevant field, also in an audience that does not have the appropriate training.

Research Seminar
  • Type of control - Защита НИР
  • Description - The main purpose of "Research Seminar": the formation of doctoral students in the skills of scientific research work. During the study of course, doctoral 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. During the study of the discipline doctoral student will learn following aspects: Determination of the direction and main stages of scientific research. Development and coordination of an individual curriculum for the doctoral student. Compilation of a literature review on the subject of the study.

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.

Teaching Internship
  • Type of control - Защита практики
  • Description - Aim оf discipline: formation of the ability to carry out educational activities in universities, to design the educational process and conduct certain types of training sessions using innovative educational technologies. During the study of course, masters should be competent in: 1. develop the taught discipline in an amount sufficient for the analytical assessment, selection and implementation of the module of the academic discipline, taking into account the level of preparedness of students, their needs, as well as the requirements of the State Educational Establishment of the Republic of Kazakhstan; 2. to develop the specifics of the organization and conduct of various types of classes in higher educational institutions (lecture, seminar, laboratory and practical); 3. apply the basic means of assessing students' academic achievements; 4. analyze the educational and methodological literature and use it to build your own presentation of program material; 5. prepare plans for seminars, practical classes, laboratory work in accordance with established methodological and methodological approaches. During the study of the discipline masters will learn following aspects: Acquaintance with the goals, objectives and content of teaching practice; drawing up of the schedule of consultations, kinds of the reporting and terms of their granting. Harmonization of the individual plan of the scientific and pedagogical practice of the undergraduate. Implementation of educational-methodical tasks coordinated with the head of practice. Visiting and analyzing the training sessions conducted by the teachers of the department. Acquaintance with the organization of scientific, methodical and educational work (plans, normative documents regulating the pedagogical process) at the faculty / at the university and the department. Development (at least 10 lessons) and conducting classes with students. Carrying out activities on the designated activities (scientific and methodological seminars, conferences, scientific circles, educational events). Preparation of an article of a scientific and methodical nature. Drawing up a report on scientific and pedagogical practice.

Data for 2017-2020 years