Applied and Engineering Physics

Discover the amazing power of physics through its applications! Learn all about lasers, super strong magnets, solar cells, biosensors and more.

Kienberger Lab Applied and Engineering Physics Master student at state-of-the–art ultrafast laser: investigation of ultrafast processes in atomes, molecules and solids will advance material science, information technology, solar energy harvesting, and bio-medical applications. Foto: TUM.PH Kienberger Lab.The Master's degree program in Physics (Applied and Engineering Physics) is a two-year international graduate program, designed to give students an insight into current research trends and new developments in modern physics.

Flyer "Applied and Engineering Physics, Master‘s Degree Program in Physics" (PDF)

Specialization Areas

Students can specialize in one or more areas of their choice:

  • Applied solid state physics -- including topics such as magnetism, semiconductor physics, applied superconductivity, spin electronics
  • Energy sciences -- including topics such as fuel cells, energy conversion, reactor physics and nuclear technology, nonlinear dynamics and complex systems, renewable energy.
  • Experimental techniques and numerical methods - including topics such as physics with neutrons, modern x-ray physics, advanced materials analysis with synchroton radiation, magnetic measurement methods.
  • High energy physics -- including topics such as particle detectors, particle physics with highest energy particle colliders, computational physics, data analysis and Monte Carlo methods.
  • Medical engineering -- including topics such as image processing in physics, biomedical physics.
  • Nanosciences -- including topics such as nanosystems, nanomaterials, nanostructured soft materials, surface and nanoscale science.
  • Plasma physics -- including topics such as plasma physics, fusion research, kinetic plasma physics, magneto hydrodynamics, turbulence in neutral fluids and plasmas.
  • Soft matter science -- including topics such as polymer physics, nanostructured soft materials.
  • Science of light -- including topics such as quantum optics, ultrafast physics and attosecond science, various light sources from infrared to X-rays, optoelectronics, ultra cold quantum gases.

A mentor can give you advice in choosing the specific courses. If you are interested in a given research area, it may be helpful to choose a mentor working in it (e.g. see the lecturers of the courses).

Typical Study Program

The study program of the first year of studies can be organized individually. The following study programs show examples of how the first year of the Master's degree program Applied and Engineering Physics could look like.

Applied Solid State Physics

ModulesCycleCP
Theoretical Physics
PH1007 Continuum MechanicsWS10
Special Courses
PH2033 MagnetismWS5
PH2155 Semiconductor PhysicsWS10
PH2157 Applied Superconductivity: Josephson Effects, Superconducting Electronics and Superconducting Quantum CircuitsSS10
PH2034 Spin ElectronicsSS5
Student Seminar, Advanced Lab Course and Non-Physics Elective Courses
Counseling by mentor4 + 6 + 8

Nanosciences

Soft Matter Science

ModulesCycleCP
Theoretical Physics
PH1007 Continuum MechanicsWS10
Special Courses
PH2046 Polymer Physics 1WS5
PH2048 Nanostructured Soft Materials 1WS5
PH2053 Physics with Neutrons 1: FundamentalsWS5
PH2047 Polymer Physics 2SS5
PH2049 Nanostructured Soft Materials 2SS5
PH2182 Modern X-Ray PhysicsWS/SS5
or  
PH2054 Physics with Neutrons 2: ApplicationsSS5
Student Seminar, Advanced Lab Course and Non-Physics Elective Courses
Counseling by mentor4 + 6 + 8

Individual Curriculum

ModulesCycleCP
Theoretical Physics
Catalog, counseling by mentor WS10
Special Courses
Catalog, counseling by mentor  30
Student Seminar
Catalog, counseling by mentor 4
Advanced Lab Course
Catalog, counseling by mentor 4
Non-Physics Elective Courses
Catalog, counseling by mentor 8