about the programme
The Physical Electronics follow-up master’s programme combines classical and modern approaches in applied physics with engineering and natural science practice. The programme is oriented toward the use of advanced physical methods, computer modelling, and modern experimental techniques in solving real-world technical and research problems.
Teaching focuses on the interactions of electromagnetic fields with materials, the functioning of photonic structures, quantum generators, and plasmas. Emphasis is also placed on their computational and experimental research methods. Laboratory courses and individual research projects are an integral part of the programme, which can lead to the publication of results or their application in engineering practice.
Students choose one of three specializations:
Laser Physics and Technology (LFT)
focused on laser generators, coherent laser beams and non-linear optics
Photonics (FOT)
focused on the field of modern photonics, optics and photonic (nano)structures, their design and applications
Computational Physics (PF)
focused on combining physics, numerical simulations, and computational modelling
Programme content
Students will attend core courses focused on:
- numerical processing and modelling of processes in medicine,
- nuclear reactor physics and thermohydraulics
- nuclear safety.
career prospects
Graduates find employment in research institutions, nuclear power plants, state administration, or industrial enterprises as developers, analysts, inspectors, or team leaders. They can also pursue careers in areas such as radioecology, radiation protection, neutron applications, or the development of nuclear technologies.
state final exam
Compulsory subject
Nuclear Engineering in Practice
Optional subjects
Nuclear Reactor Physics
Design of Nuclear Reactors
Safety and Operation of Nuclear Installations
Exploitation of Nuclear Reactors
Measurement and Evaluation Methods of Ionizing Radiation
Nuclear and Radiation Physics
Computational Methods in Radiation Physics