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)

  • Advanced biostatistics (Z. Somogyvári)
  • Algebraic quantum field theory (P. Vecsernyés)
  • Cognitive neuroinformatics II, Budapest Semester in Cognitive Sciences (Z. Somogyári)
  • Cognitive neuroscience, Budapest Semester in Cognitive Sciences, (L.Négyessy)
  • Computational neuroscience (Z. Somogyvári)
  • Electrodeposition of metals (L. Péter)
  • Experimental methods of structure determinationI-II. (L. Temleitner)
  • Integrable methods in the gauge/gravity duality I (Z. Bajnok)
  • Introduction to cognitive science, Budapest Semester in Cognitive Sciences, (P. Érdi)
  • Introduction to gravitational theory and high-energy physics (G.G. Barnaföldi, M. Vasúth)
  • Introduction to general relativity (M. Vasúth)
  • Investigation of the inner structure of compact stars (G.G. Barnaföldi)
  • Macromolecules (S. Pekker)
  • Many-body problem I-II. (G. Szirmai)
  • Nanophase metals (I. Bakonyi)
  • Neurophysiological data analysis (Z. Somogyvári)
  • Neutron physics (M. Márton)
  • Nuclear solid-sate physics I-II (D.L. Nagy)
  • Optics and relativity theory (J. Cserti, Gy. Dávid, D. Varga)
  • Physics of jets (P. Lévai)
  • Physics of liquid crystals and polymers (Á. Buka and N. Éber)
  • Physics of the solar system (Z. Németh)
  • Plasma physics (Z. Donkó)
  • Raman spectroscopy in Earth sciences (T. Váczi)
  • Scientific programming for graphics processors I. (M.F. Nagy-Egri)
  • Scientific programming for graphics processors II. (D. Berényi)
  • Selected chapters from high-energy experimental physics (multiple lecturers, including
  • A. László, D. Varga)
  • Selected chapters on compact star interior (G.G. Barnaföldi)
  • Selected topics in experimental high-energy physics (F. Siklér, R. Vértesi)
  • Solid State Physics (I. Tüttő)
  • Statistical physics (G. Szirmai)
  • String Theory (Z. Bajnok)
  • Superconductivity (I. Tüttő)
  • The phase-structure of the strongly interacting matter (P. Lévai)
  • Trends in materials science (Á. Gali)
     

Budapesti Műszaki és Gazdaságtudományi Egyetem (BME)

  • Coherent control of quantum systems (Z. Kis)
  • Engineering thermodynamics II. (R. Kovács)
  • Fusion devices (G. Veres)
  • Fusion devices (G. Pokol)
  • Group theory in solid state research (G. Kriza)
  • Industrial systems diagnostics (G. Pokol, guest lecturer)
  • Inertial confinement fusion (single lecture within the course “Introduction to the fusion
  • plasma physics” of G. Pokol) (I. Földes)
  • Infrared and Raman spectroscopy (K. Kamarás)
  • Interacting spins in materials (K. Penc)
  • Introduction to fusion plasma physics (G. Pokol, S. Zoletnik, D. Dunai)
  • Introduction to irreversible thermodynamics (P. Ván)
  • Introduction to superconductivity (G. Kriza)
  • Introduction to theoretical plasma physics (A. Bencze)
  • Investigation techniques for materials science (T. Keszthelyi)
  • Mechanics I-II. (A. Virosztek)
  • MHD in low dimensional systems (A. Bencze)
  • Modern nuclear energy (G. Pokol)
  • Modern solid state physics (A. Virosztek)
  • Neutron physics (M. Márton)
  • Nuclear fuel cycle (M. Fábián)
  • Nuclear physics (G. Pokol, guest lecturer)
  • Numerical simulations of caloric machines (R. Kovács)
  • Plasma physics (Z. Donkó)
  • Quantum entanglement (Sz. Szalay)
  • Quantum optics (P. Domokos) 
  • Quantum optics (J.K. Asbóth)
  • Spectroscopy and the structure of matter (K. Kamarás)
  • Theoretical solid state physics (A. Virosztek)
  • Theory of magnetism (A. Virosztek)
  • Variational methods in the basics laws of physics (T.S. Biró)
     

Semmelweis Egyetem (SOTE)

  • Learning and navigation, Systems Neuroscience Summer School, (Z. Somogyvári)
  • Neocortex: from structure to function, Systems Neuroscience Summer School (L.Négyessy)
  • Neuroinformatics (L. Négyessy, F. Bazsó, L. Zalányi, Z. Somogyvári)

Óbudai Egyetem

  • Chemistry and Physics of Polymers (S. Pekker)
     

Szent István Egyetem, Gödöllő

  • Biophysics (I.F. Barna, in German)
     

Szegedi Tudományegyetem

  • Analytical mechanics (L. Fehér)
  • Applications of statistical physics (F. Iglói)
  • Introduction to statistical physics (F. Iglói)
  • Introduction to the physics of laser plasmas (I. Földes)
  • Introduction to the theory of nonlinear laser-matter interactions (S. Varró)
  • Modeling heavy-ion collisions (Gy. Wolf)
  • Nuclear and particle physics (L. Fehér)
  • Statistical physics (F. Iglói)
  • Symmetries in physics (L. Fehér)
  • The properties of dense, strongly interacting matter (Gy. Wolf)
     

Pécsi Tudományegyetem

  • Algebra and number theory II-III. (J. Laczkó)
  • Control and regulation technology (J. Laczkó)
  • Control systems (J. Füzi)
  • Digital control (J. Füzi)
  • Electronics (J. Füzi)
  • Geometry and visualisation (J. Laczkó)
  • Mechanics - dynamics (A Len)
  • Neurobioinformatic programming (J. Laczkó) 
  • Numerical methods (P. Ádám)
  • Open quantum systems (P. Ádám)
  • Probability theory (P. Ádám)
  • Quantum information processing by quantum optical means II. (T. Kiss)
  • Resonant light-matter interaction (P. Ádám)
  • Seismic design (A. Len)
  • Statistical physics (K. Szlachányi)
  • Theoretical mechanics (K. Szlachányi)
  • Theoretical physics III (P. Ádám)
     

Debreceni Egyetem

  • Particle physics 1 and 2 (D. Horváth)
  • Particle physics exercises (D. Horváth)
  • Structure and experimental test of the standard model 1 and 2 (D. Horváth)
     

Oulu University, Oulu, Finland

  • Lecture course on nanophase metals with special view on spintronics (I. Bakonyi)
     

Pázmány Péter Katólikus Egyetem

  • Basic calculus (B. File)
  • Neuoromorph movement control. (J. Laczkó)
  • Research methods in sociology, (B. File)
  • Webmining (B. File)
     

Szabadkai Műszaki Szakfőiskola (Szerbia)

  • Physics of enginiering, (F. Bazsó)
     

Állatorvostudományi Egyetem

  • Biophyics (Z. Szőkefalvi-Nagy, both in Hungarian and in English, two courses)
     

University of Warsaw (Lengyelország)

  • On the use of evolutionary methods in metric theories of gravity (I. Rácz)

 

Gyakrolatok és szemináriumok
 

Eötvös Loránd Egyetem, Budapest

  • Advanced physics laboratory (R. Vértesi)
  • Atomic and molecular physics (P. Udvarhelyi)
  • Differential equations in Physics II (T. Gombor)
  • Electrodynamics (M. Lajer)
  • Environmental radiations laboratory (G. Galgóczi)
  • Experiments on liquid crystals (Á. Buka, N. Éber, P. Salamon, T. Tóth-Katona)
  • IT tools for research (G. Biró, M.F. Nagy-Egri)
  • Laboratory practice on neutron scattering (L. Almásy, A. Len, M. Fábián, L. Rosta, T. Veres, Gy. Török)
  • Modern physics laboratory (P. Udvarhelyi)
  • Nuclear techniques and X-ray spectroscopy (Z. Németh)
  • Nuclear techniques for elemental analysis (RBS and ERDA), extended practice for physics students (E. Szilágyi) 
  • Particle, nuclear and astrophysics lab / MHD waves (A. Opitz)
  • Particle and nuclear physics detectors laboratory (G. Hamar, D. Varga)
  • Probability theory (M. Kornyik)
  • Probability theory and statistics (M. Kornyik)
  • Quantum mechanics (M. Lajer)
  • Raman spectroscopy, part of the course Laboratory practice in biophysics (M. Veres)
  • Statistical physics (G. Szirmai)

Budapesti Műszaki és Gazdasági Egyetem

  • Applied thermodynamics (R. Kovács)
  • Engineering thermodynamics II (R. Kovács)
  • Heat and flow transfer in mechatronics elements (R. Kovács)
  • Independent task I-II. (L. Bencs)
  • Individual project (D. Beke)
  • Infrared and Raman spectroscopy (K. Kamarás)
  • Introductory physics for chemical engineers (A. Csóré)
  • Laboratory practice (M.A. Kedves, B. Ráczkevi)
  • Laboratory practice on neutron scattering (L. Almásy, A. Len, M. Fábián, L. Rosta, T. Veres, Gy. Török)
  • Nuclear- and neutron physics practical lesson (G. Nyitrai)
  • Physics II for electrical engineers (A. Csóré)
  • Physics II for informaticians (A. Csóré)
  • Physics II. for IT students (A. Buzás)
  • Quantum mechanics (Z. Kökényesi)
  • Raman spectroscopy, part of the course Experimental methods in materials science (M. Veres)
  • Remote measurement on the GOLEM tokamak (G. Pokol)
  • SUMTRAIC Summer School (A. Bencze)
  • Thermal physics, mechatronics I-II.(P. Ván)
  • Thermodynamics and heat transfer (R. Kovács)

Pécsi Egyetem

  • Biorobotics (J. Laczkó) 
  • Control systems I-II (J. Füzi)
  • Diagnostics – SEM laboratory practice (A. Len)
  • Geometry and visualisation (J. Laczkó)
  • Mathematical methods in physics IV. (D. Jakab)
  • Mathematical methods in physics IV. (P. Ádám)
  • Mechanics – dynamics - seminar (A. Len)
  • Professional commuication (J. Laczkó)
  • Probability theory (P. Ádám) 

Szegedi Tudományegyetem

  • Summer practice in the HILL laboratory, high intensity laser-plasma interactions (I. Földes)
  • Physics practice for 1st year BSc students and for 1st year MSc students (I. Földes, Zs. Kovács)
  • Electronics laboratory (Zs. Kovács)
  • Physics and biophysics laboratory practice (Zs.Kovács)

Eszterházy Károly Egyetem (Eger)

  • Statistics I. (G. Kasza)
  • Statistics II. (G. Kasza)
  • Mathematics for economy I. (G. Kasza)

Pázmány Péter Katólikus Egyetem (Budapest)

  • Neuoromorph movement control (L. Botzheim)