Master's in Engineering in Russia

View Master Degrees in Engineering in Russia


In order to successfully obtain a Masters qualification, you will need to obtain a number of credits by passing individual modules. Most taught Masters will have a number of core modules which you must take and pass in order to obtain the qualification. The assessment of research Masters is almost always entirely by a single dissertation module or project.

Improvements made to manmade things such as tools, structures and machines are largely due to the efforts of people in the field of engineering. These people combine creativity with mathematics and worldly knowledge, resulting in innovation.


Russia or, also officially known as the Russian Federation, is a country in northern Eurasia. Education in Russia is provided predominantly by the state and is regulated by the Ministry of Education and Science. In Russia, it takes about 70 % of training time for the contact lessons with a teacher, the rest 30 % of the workload are devoted to the independent study of the material.

Master's Degree in Engineering in Russia

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Master in Advanced Metallic Materials and Engineering

National University of Science and Technology MISiS
Campus Full time October 2017 Russia Moscow

The MS program “Advanced Metallic Materials and Engineering” offers high-quality postgraduate education in non-ferrous physical metallurgy and mechanical and aerospace engineering. [+]

Master in Advanced Metallic Materials and Engineering

A MS program “Advanced Metallic Materials and Engineering” offers high-quality postgraduate education in mechanical and aerospace engineering, and non-ferrous physical metallurgy.

Total amount of Academic Credits: 120 credits.

Academic Credits for R&D work and dissertation: 45 credits.

Academic Credits for educational courses: 75 credits.

The medium of instruction for this program is English.

Program’s content

During their study, students will actively use technical equipment that will help them test their theoretical knowledge in experimental setting. The educational process is based on the modular system, which allows students to choose the courses they deem necessary and beneficial for their future career from a total number of courses offered by the program.... [-]

Master in Multicomponent Nanostructured Coatings. Nanofilms

National University of Science and Technology MISiS
Campus Full time October 2017 Russia Moscow

This two-year master's program combines advanced lectures and practical training related to Nanofilms and Multicomponent Nanostructured Coatings. [+]

New materials form the basis for modern technologies, and both industry and research related to and dealing with nanomaterials are among those to experience fast growth within this century. Nanotechnology combines all the techniques and approaches that manipulate matter on the nanometer-scale, focusing, in its practical aspects, on the development of materials with novel, sometimes unique, properties. Nanotechnology-based industries have an enormous potential to produce new high-quality products in many sectors, thus changing and improving the quality of human life. Importantly, the progress in nanotechnologies offers not just better products, but also significantly improved manufacturing processes and analytical techniques.... [-]

Master in Quantum Physics for Advanced Materials Engineering

National University of Science and Technology MISiS
Campus Full time October 2017 Russia Moscow

Master's program "Quantum Physics for Advanced Materials Engineering" is devoted to the study of new physical phenomena in nanostructured materials and quantum devices created or discovered during the last 20-30 years of research for components for quantum electronics. [+]

Best Masters Programs in Engineering in Russia. The Master's program Quantum Physics for Advanced Materials Engineering is devoted to the study of new physical phenomena discovered in nanostructured materials and quantum devices created last 20-30 years in the search for components for quantum electronics. At the same time the program addresses the basic physical principles of electronic systems and devices of quantum electronics, as well as some important manufacturing techniques and measurements of physical and chemical characteristics of quantum-sized structures and materials. The program is designed for students trained in the amount of university courses in general physics and introduction to theoretical physics for a Bachelors, which includes the courses: theoretical mechanics and the theory of elasticity,electrodynamics, quantum mechanics and statistical physics. The program does not involve a starting special training of students in the condensed matter physics,, because it includes basic courses in: 1) modern quantum physics of solids, 2) electronic theory of metals, 3) technology and materials of quantum electronics, 4) spectroscopic methods of materials characterization. The medium of instruction for this program is English. The urgency and necessity A distinctive feature of this Master’s program is to focus on the study of new physical phenomena in quantum-sized materials and devices, all of which are overlooked in traditional courses of solid state physics. These objects of study appeared in the last 20-30 years due to development of tools and methods of measurement and conversion of properties of materials in the nanometer range of distances. Although the physical phenomena and processes observed in the new materials and nanostructures are described in the framework of well-established fundamental concepts of quantum and classical physics, they could not become an object of study of traditional training courses on condensed matter physics, which were created in the middle of the twentieth century, simply because most of these facilities and adequate measurement tools for their research were not yet developed. The circle of new physical phenomena studied in special courses of this master's program includes the effects of size quantization in low-dimensional structures, in particular: the quantum Hall effect, quantum charge fluctuations, Coulomb blockade and Landauer quantum conductance of the contacts of atomic size, the Wigner-Dyson statistics of electronic energy levels in the nanoclusters, the Rabi oscillations in two-level systems, the spectra of quantum dots, wells and wires in a magnetic field, phonons in fractal structures, Einstein modes in thermoelectric semiconductor materials with complex crystal cell, etc. Developing skills This master's program enables students to orient themselves in the modern scientific and applied research and development of quantum-sized materials and devices through the acquisition of skills in both theoretical calculations in the field of quantum physics of nanosystems as well as experimental measurements using modern equipment in the field of electron and scanning probe microscopy and spectroscopy. Basic Courses 1) Modern quantum physics of solids (1 st semester) introduces into: different aspects of modern solid state physics, including phenomena in the objects of atomic size, including those considered in the following topics: quantum Hall effect, graphene and carbon nanotubes, Landauer quantum conductance of atomic size contacts, quantum magnets (spin chains), magnetism of frustrated systems, magnetic semiconductors, including silicon doped with manganese, colossal magnetoresistance, quantum phase transitions, the low-energy excitations in disordered media and fractal structures, granular conductors, metals with heavy fermions, the Kondo semiconductors, quasicrystals and structurally complex alloys; 2) Electron theory of metals (1 st semester) introduces into: basic methods and results of the electron theory of metals, that are in the focus of the current research of quantum properties of solids and use the concept of Landau quasi-particles and Fermi-liquid theory to describe the properties of normal metals; description of phenomena in superconductors, based on the concept of spontaneous symmetry breaking and Bose-condensation of Cooper pairs in the framework of the theory of Bardeen, Cooper and Schrieffer, with application of the equations of the Ginzburg and Landau; foundations of the Green's functions technique and its applications for prediction and interpretation of experiments involving the scattering of photons, neutrons, muons and measuring the current-voltage characteristics of the tunneling microcontacts; 3) Technologies and Materials of Quantum Electronics (2 nd semester) introduces into: physical properties of basic semiconductor materials and methods of nanotechnology in relation to the creation of the base elements of nanoelectronics, optoelectronics, quantum devices, in particular, including the study of changes in the electrical and optical properties of bulk materials when they are produced in the form of low-dimensional structures (quantum wells, wires and dots) due to the effects of quantum-size effect; with the emphasis on C, Si, solid solutions GeXSi1 -X , compounds and solid solutions А2В6 and A3B5; also considered are basic technologies of manufacturing of quantum-sized structures: liquid phase epitaxy, molecular beam epitaxy, vapor phase epitaxy of organometallic compounds, nanolithography, self-organization of quantum wires and dots; outline of the use of low-dimensional structures in the devices of micro-and nanoelectronics; also considered are emitting diodes and lasers for the infrared, visible and ultraviolet spectral regions, photodetectors and transistors; 4) Spectroscopic methods for analysis of materials (1 st semester) introduces into: the fundamentals of modern spectroscopic methods of analysis of materials, such as Auger electron spectroscopy (AES), X-ray photoelectron spectroscopy (XRF), secondary ion mass spectrometry (SIMS), transmission electron microscopy (TEM), scanning ion microscopy (SIM), i.e. methods that allow us to investigate elemental, chemical composition, atomic structure, structural perfection of the surfaces of solids, surface layers, interphase boundaries and nanostructures. Special Courses familiarize students with basic modern areas of theoretical physics research in nanosystems, in including low-dimensional systems. 1) Quantum electronic properties of nanosystems (3rd semester) introduces into: theory of electronic quantum phenomena in nanosystems: random Hamiltonian matrices of Wigner-Dyson and thermodynamics of nanoclusters, Peierls transitions in quasi one-dimensional conductors, transitions of Ising and Berezinskii Kosterlitz-Thouless in two-dimensional lattice systems, the theory of spin fluctuations in one-dimensional Ising chain, the theory of Landauer quantum conductance of quantum point contact; 2) Physics of liquid-crystal membranes (3rd semester) introduces into: physics of liquid crystals and its applications to the theory of lipid membranes, in particular, into fundamentals of elasticity of liquid crystals adapted to describe bilayer membranes, thermodynamics and kinetics of phase transitions in multicomponent systems, Gibbs phase diagrams and various two-dimensional lattice models; basic theory of wetting, adapted to biomembranes, mechanisms of protein-lipid interactions and conditions of formation of macroscopic wetting films, the dependence of the rate of cellular processes on the energy of forming membrane structures using exo-and endocytosis as example; 3) Physics of Low-Dimensional Systems (2 nd semester) introduces into: low-dimensional systems - quasi-two-dimensional quantum wells, one-dimensional quantum wires and quasi zero-dimensional quantum dots, in particular, with the quantum-mechanical phenomena in such systems and the influence of external electric and magnetic fields, methods of computer modeling and calculations from first principles of parameters of the low-dimensional systems: resonant frequencies, the energy spectra and wave functions of electronic and excitonic systems with carriers incoupled quantum wells and coupled quantum dots; evolution of the spectrum and restructuring of the spin states of molecules consisting of horizontally and vertically coupled quantum dots; 4) Experimental Methods in the physics of low-dimensional systems (2-nd semester) introduces into: methods of experimental studies of transport and magnetic properties of solids, including: galvanomagnetic effects (magnetoresistance, Hall effect, de Haas-van Alphen effect, Shubnikov - de Haas effect), electrodynamics of metals, nuclear magnetic resonance, nuclear gamma resonance; equipment and experimental techniques of measurement of weak signals in the presence of noise, resistance measurement, thermometery, application of high magnetic fields; methods of choice of appropriate measurement technology for research, experimental design, design scheme of the experimental setup, processing and interpretation of the results of the experiment, the course also teaches methods of analysis of surfaces of solids, including: classification of methods of analysis of materials surface, ion-beam probe (inverse Rutherford scattering, channeling, mass spectroscopy of secondary ions), electron-beam probe (characteristic loss spectroscopy, secondary electron emission, Auger spectroscopy), electromagnetic radiation probe, tunneling microscopy; 5) Phase diagrams of multicomponent systems (3rd semester) introduces into: analysis of phase diagrams of multicomponent systems, including applied to real materials and processes based on software packet calculation methods “Thermo-Calc”, as well as the original techniques focused on the use of widespread program EXCEL; methods of solution of the following tasks: analysis of phase composition of multicomponent materials at different temperatures; graphical estimate and calculation of the liquidus, solidus, and other critical temperatures of phase transformations; construction of insulated and polythermal cuts of triple, quadruple and five fingers systems using both graphical and computational methods; calculation of the mass and volume fractions of phases in multicomponent systems, a critical analysis of information on phase diagrams and finding errors in the prediction of phase equilibria in unexplored multicomponent systems. 6) Electronic properties of quantum confined semiconductor heterostructures (2–nd semester) introduces into: physics of low dimensional quantum confined heterostructures, that are the structures where the carrier motion is restricted in one or more directions at the distances of the order of de Broglie wavelength; electron transport and optical transitions in low dimensional electronic systems, and the difference between the electronic properties of low dimensional structures and those of bulk semiconductors; applications of quantum dots and wells in photovoltaics and laser techniques. 7) Introduction to path integral methods in condensed matter physics (2–nd semester)motivation and contents: The idea of the course is to get students acquainted with path integral approach to problems of contemporary condensed matter physics. The aim is to give students firm command of this approach via carefully selected examples and problems. The course contains mathematical digression into complex calculus, the basics of second quantization, field quantization, path integral description of quantum statistical mechanics, finite temperature perturbation theory, theory of linear response, basics of renormalization group analysis and effective field theory. The final project consists of the theoretical description of single electron transistor via effective Ambegaokar-Eckern-Schoen action. Courses in experimental research methods help students to get an idea of materials for prospective elementary base of quantum electronics, as well as on the possibilities of measurement methods: 1) spectroscopy, 2) tunneling microscopy, 3) scanning ion microscopy, 4) the accuracy, sensitivity, locality, and applicability of different measurement methods for the study of nanomaterials. Focus of lecture courses are new materials and modern quantum devices. List of new materials studied in the course of the program includes: 1) graphene and carbon nanotubes 2) quantum magnets - atomic spin chain 3) magnetic semiconductors - silicon doped with manganese; 4) semiconductor materials based on solid solutions of germanium in silicon 5) disordered media and fractal structures – aerogels, granular conductors, 6) heavy fermionic metals, the Kondo semiconductors, 7) quasicrystals and structurally complex thermionic materials based on bismuth telluride. Studied electronic devices and appliances include: 1) tunnel contact of atomic size, 2) magnetic switches on the basis of manganites with colossal magnetoresistance 3) Josephson junctions 4) emitting diodes and lasers for the infrared, visible and ultraviolet, photodetectors, transistors. Studied manufacturing technologies of quantum-sized materials: 1) liquid-phase epitaxy, 2) molecular-beam epitaxy, 3) vapor-phase epitaxy from organometallic compounds, 4) nanolithography, 5) self-organization of quantum wires and dots. Admission Admission to International Master’s Programs at MISiS is open to both Russian and international students. Given that all classes will be conducted in English, we recommend that nonnative speakers of English achieve a TOEFL score of at least 525 (paper based) or 200 (computer based) prior to admission. To apply for a two-year Master’s program at MISiS, the applicant must hold a Bachelor’s degree in a related field. Upon the completion of the program of study at MISiS, the applicant will receive a Russian State diploma and a European Diploma Supplement. Admission Deadline The deadline to submit the application for Fall 2017 is 10 May 2017. [-]

Master in Laser Measuring Technology

Saint Petersburg Electrotechnical University
Campus Full time September 2017 Russia St. Petersburg

Students get knowledge of quantum electronics and laser techniques. [+]

The structure of degree program consists of advanced professional studies, elective studies and a Masters Thesis. Students get knowledge of quantum electronics and laser techniques. They get skills of practical work with modern laser techniques and laser measurement equipment, ability of carrying out science research during development of new laser measuring devices and systems. As a result we achieve competitiveness of our graduates and their job placement in prestigious research institutes and firms. Program curriculum includes the following advanced courses: Wave Optics Optical systems and components Theoretical Principles of Quantum Devices Laser systems Fiber and Integrated Optics Laser measurement systems Methods and means of laser radiation control Laser and fiber optic technology in navigation systems Optoelectronics Programme: 120 ECTS credits, full-time study (2 years), Master’s Degree Eligibility: candidates must hold a Bachelor's Degree in the corresponding field Scholarship: scholarship covers the tuition fee and some study materials An academic year includes 2 semesters beginning on 1st September and 10th February, Winter holidays - 2 weeks, Summer holidays - 2 months (July, August). Master’s Thesis defense is in June. Educational programs of «LETI» are constantly modernized, following the principle «Training through research». Graduates of our university receive new, profound knowledge and practical skills of work. [-]

International Master in Energy Technology

Peter the Great St. Petersburg Polytechnic University
Campus Full time September 2017 Russia St. Petersburg

The purpose of the Master of Science in Energy Technology degree programme is to prepare highly qualified professionals capable to solve complex engineering and management tasks in the world energy industry. [+]

International Master Degree Programme: Energy Technology

The 5 best reasons to participate in the program

1. The Master’s Degree Programme in Energy Technology includes a wide array of energy studies aimed to fundamental preparation and practical training.

2. The programme is conducted with the participation of key professors of St. Petersburg State Polytechnical University and other leading Russian and foreign universities.

3. The programme contributes to joint study of Russian students with foreign students, the opportunity to participate together in academic and extracurricular activities of SPbSPU.

4. The programme offers a unique opportunity to undertake an internship in leading Russian energy companies and a semester abroad at foreign partner University.... [-]

Master - Offshore and Coastal Engineering

Far Eastern Federal University
Campus Full time September 2017 Russia Vladivostok

The two-year Master of Science program in Offshore and Coastal Engineering was designed to meet the growing demand for skilled professionals in the offshore and coastal construction industry. The [+]

Master - Offshore and Coastal Engineering

The two-year Master of Science program in Offshore and Coastal Engineering was designed to meet the growing demand for skilled professionals in the offshore and coastal construction industry. The program consists of general principles and methods that give students the tools to meet and solve challenges on an advanced engineering level, not only inside their area of specialization. Projects and problems in the program are often taken from the offshore industry, and students gain valuable experience due to the School's close contacts with the industry.

Educational objectives of the program

To give students a high level of understanding and advanced analytical skills in key areas of offshore and coastal engineering including: exploration of ocean resources, development of infrastructure of offshore oil and gas industry and marine transport;  to satisfy students’ personal needs in qualified professional education on the basis of common cultural and professional competences  including Federal State Educational Standards and requirements of job offers. ... [-]

Master in Control in Engineering Systems

Nosov Magnitogorsk State Technical University
Campus Full time September 2017 Russia Chelyabinsk

The development of high-performance automation systems and automated process control system (APCS) in various industries is the important factor in the creation of new efficient production. [+]

Master's Degree ProgramCourse - Control in Engineering Systems

Production processes intensification, productivity increase, expenses decrease in industrial production is impossible without modern automated systems. The development of high-performance automation systems and automated process control system (APCS) in various industries is the important factor in the creation of new efficient production.

This master's degree program in Control in Engineering Systems endows the graduate with theoretical knowledge and practical experience in the development and implementation of automated control systems of production and engineering systems.

As a graduate of Master's Degree Program in Control in Engineering Systems, you will be prepared to demonstrate the ability in:... [-]

Master in Engineering - Standardization and Metrology

Nosov Magnitogorsk State Technical University
Campus Full time September 2017 Russia Chelyabinsk

Master's Degree Program covers a broad range of subjects which provide students with the foundation in the field of standardization, metrology and certification of quality control for the metalworking industries. [+]

Master's Degree in EngineeringCourse - Standardization and Metrology

Solving the problems of integration interaction in the international community is impossible without the expert participation in the field of metrology, standardization, confirmation and quality control in production systems. The conformity assessment procedures can make a major contribution to the achievement of specific objectives of the countries national policies, the abolition of trade barriers. They can balance the free circulation of commodities in the domestic market with the requirement to provide a "high level of health, safety and environment protection and advocate consumer interests".

Nosov Magnitogorsk State Technical University offers a master's degree for students interested in standardization, metrology and certification.... [-]