Az itt felsorolt kurzusok és szemináriumok általában minden évben meghirdetésre kerülnek, azonban az aktuális év tanmenetéről érdemes mindig az adott egyetemtől érdeklődni!

Graduális és posztgraduális kurzusok

 Eötvös Loránd Tudományegyetem (ELTE)

• Algebraic Bethe Ansatz and its applications (F. Woynarovich)
• Cavity Quantum Electrodynamics (P. Domokos, J. Asbóth)
• Cognitive Neuroscience (L. Négyessy)
• Completely integrable many body systems (F. Woynarovich)
• Computational Neuroscience (Z. Somogyvári)
• Electrodeposition of metals (L. Péter)
• Electrons in solids (I. Tüttő)
• Electrons in solids (J. Sólyom)
• Inner structure of compact stars (G.G. Barnaföldi and M. Vasúth)
• Introduction to general relativity, (I. Rácz)
• Introduction to general relativity, (M. Vasúth)
• Introduction to gravitational theory and high energy physics (G.G. Barnaföldi and M. Vasúth)
• Jet physics (P. Lévai)
• Liquid crystals, their chemistry and chemical physics (K. Fodor-Csorba)
• Macromolecules I. (S. Pekker)
• Many-body physics I. (G. Szirmai)
• Many-body physics II. (G. Szirmai)
• Nanomagnetism (J. Balogh)
• Neural Modelling (Z. Somogyvári, M. Bányai, D. Cserpán)
• Nuclear Solid State Physics I (D.L. Nagy)
• Nuclear Solid State Physics II (D.L. Nagy)
• Open Quantum System Theory (L. Diósi)
• Pattern formation in complex systems (Á. Buka and T. Börzsönyi)
• Phase structure of strongly interacting matters (P. Lévai)
• Physics of liquid crystals and polymers (Á. Buka and N. Éber)
• Physics of low temperature plasmas (Z. Donkó)
• Physics of the heliosphere (G. Erdős)
• Plasma physics of the Solar System (K. Szegő)
• Relativistic heavy ion collisions (P. Lévai)
• Renormalization methods for strongly correlated systems (Ö. Legeza)
• Superconductivity (I. Tüttő)
• Topological insulators (J. Asbóth)

Budapesti Műszaki és Gazdaságtudományi Egyetem (BME)

• Advanced thermodynamics (P. Ván)
• Coherent control of quantum systems (Z. Kis)
• Group theory  in solid state research (G. Kriza)
• Infrared and Raman spectroscopy (K. Kamarás)
• Infrared vibrational spectroscopy, part of the course Experimental methods in materials science (L. Kovács)
• Interacting spin systems (K. Penc)
• Introduction to theoretical plasma physics (A. Bencze)
• Investigation methods in materials science (M. Bokor and K. Tompa)
• Ion beam analysis, part of the course Experimental methods in materials science (E. Szilágyi)
• MHD in low-dimensional systems (A. Bencze)
• Neutron scattering I, part of the course Experimental methods in material science (B. Nagy, L. Bottyán)
• Nuclear Solid State Physics I (D.L. Nagy)
• Nuclear Solid State Physics II (D.L. Nagy)
• Physics of low temperature plasmas (Z. Donkó)
• Raman spectroscopy, part of the course Experimental methods in materials science (M. Veres)
• Spectroscopy and structure of matter (K. Kamarás)
• Superconductivity (G. Kriza)

Semmelweis Egyetem (SOTE)

• Neuroinformatics (L. Négyessy, F. Bazsó, Z. Somogyvári, L. Zalányi, M. Bányai)

Óbudai Egyetem

• Chemistry and Physics of Polymers (S. Pekker)

Szent István Egyetem, Gödöllő

• Biophyics (Z. Szőkefalvi-Nagy, SZIE AOTK)
• Computer Aided Engineering (L. Zoltan)
• Machine elements I. (L. Zoltan)
• Machine elements II. (L. Zoltan)

Szegedi Tudományegyetem

• Analytical mechanics (L. Fehér)
• Application of statistical physics (F. Iglói)
• Experimental methods of nuclear physics (T. Csörgő)
• Fundamental processes in nonlinear laser-matter interactions (S. Varró)
• Introduction to theoretical physics I. (L. Fehér)
• Nuclear and Particle Physics I (T. Csörgő)
• Physics of amorphous matter I-II (M. Koós)
• Quantum field theory (L. Fehér)
• Selected topics in mathematical physics (L. Fehér)
• Statistical physics (F. Iglói)

Pécsi Tudományegyetem

• Calculus I. (K. Szlachányi)
• Calculus II. (K. Szlachányi)
• Control theory (J. Füzi)
• Digital Control (J. Füzi)
• Electronics (J. Füzi)
• Mathematical methods in physics IV. (P. Ádám)
• Numerical methods (P. Ádám)
• Operating systems (B. Kollár)
• Physics of gas discharges (Z. Donkó)
• Probability theory (P. Ádám)
• Quantum mechanics I. (J. Janszky)
• Quantum mechanics II. (J. Janszky)
• Quantum mechanics II. (P. Ádám)
• Statistical physics (K. Szlachányi)
• Theoretical physics III. (P. Ádám)

Debreceni Egyetem

• Particle Physics, MSc Course (D. Horváth)
• Quantum Field Theory (T.S. Biró)
• Structure and Experimental Test of the Standard Model, PhD Course (D. Horváth)

Rolls-Royce University Technology Centre, Cambridge University, UK

• Phase field modelling and solidification (L. Gránásy, T. Pusztai, G. I. Tóth, G. Tegze)

Gyakrolatok és szemináriumok

Eötvös Loránd Egyetem, Budapest

• Experiments on liquid crystals (Á. Buka, N. Éber, T. Tóth-Katona)
• Laboratory for solid state physics, Preparation and crystallization of metallic glasses (I. Vincze)
• Laboratory practice (T. Pusztai)
• Laboratory practice in solid state physics and materials science (K. Tompa and M. Bokor)
• Physical chemistry laboratory practice (L. Péter, B. Tóth)
• RBS and ERDA analysis, extended practice for physics student (E. Kótai).
• Solar-terrestrial relation for astrophysics students (M. Tátrallyay)
• Solid-state physics seminar (I. Tüttő)
• Solid-state physics seminar (J. Sólyom)

Budapesti Műszaki és Gazdasági Egyetem

• Infrared and Raman spectroscopy (K. Kamarás)
• Infrared vibrational spectroscopy, part of the course Experimental methods in materials science (K. Lengyel)
• Laboratory practice on investigation methods in materials science (M. Bokor and K. Tompa)
• Practice course in experimental physics for engineer-physicists (A. Szakál)
• Practice course in electrodynamics for energy-engineers (A. Szakál)
• Problem solving courses in thermodynamics (T. Fülöp)
• Problem solving course in heat exchange (P. Ván)
• Raman spectroscopy, part of the course Experimental methods in materials science (M. Veres)
• Seminar to the Physics 2 course for bachelor students in electrical and software engineering (B. Nagy)

Pécsi Egyetem

• Control theory seminar (J. Füzi)
• Electronics laboratory practice (J. Füzi)
• Operating systems (B. Kollár)