MQV research groups
We have a wide range of expertise in the field of quantum science, as can be seen from the list of our research groups.
| Research Group | Affiliation(s) | Keywords | |
| Prof. Monika Aidelsburger | LMU-PH | quantum simulator, cold atoms in optical lattices | |
| Prof. Mikhail Belkin | TUM-CIT / WSI | optoelectronics, integrated photonics, metamaterials | |
| Prof. Pramod Bhatotia | TUM-IN | operating systems, distributed architectures, virtualization | |
|
Dr. Sebastian Blatt |
MPQ | quantum simulator, cold atoms in optical lattices | |
| Prof. Immanuel Bloch |
LMU-PH, MPQ |
quantum simulator, cold atoms in optical lattices, rydberg atoms |
|
| Prof. Holger Boche | TUM-CIT | quantum information theory, quantum computing, quantum communication | |
| Prof. Martin Brandt | TUM-PH / WSI | dopants and defects in semiconductors for quantum applications, EPR, ESR | |
| Dr. Christian Carlowitz | FAU-EEI | millikelvin electronics, RF system design, RF measurement techniques, applied quantum technologies | |
| Prof. Juan Ignacio Cirac | MPQ / TUM-PH | quantum optics, quantum information theory, quantum many-body physics, tensor networks | |
| Dr. Frank Deppe | TUM-PH / WMI | solid-based quantum systems, superconducting quantum circuits, quantum communication, quantum sensing | |
| Dr. Christian Deppe | TUM-EI | quantum information theory, quantum communication, quantum networks | |
| Prof. Claudia Eckert | FhG-AISEC / TUM-IN | quantum cryptography, static code analysis, secure/private computation, machine learning applications for IT Security | |
| Prof. Martin Eckstein | FAU-PH | strongly correlated quantum many-body systems, non-equilibrium quantum dynamics, dynamical mean-field theory | |
| Prof. Dmitri K. Efetov | LMU | low-dimensional quantum materials, quantum sensing, quantum networks | |
| Prof. Stefan Filipp | TUM-PH / WMI | solid-based quantum systems, superconducting quantum circuits, nanomechanical systems | |
| Prof. Jonathan Finley | TUM-PH / WSI | semiconductor nanostructure, nanotechnology, quantum optics | |
| Dr. Simon Fölling | LMU-PH | quantum simulator, cold atoms in optical lattices | |
| Prof. Steffen Glaser | TUM-CH | nuclear magnetic resonance, magnetic resonance imaging, quantum computing, biopolymers | |
| Prof. Rudolf Gross | WMI / TUM-PH | solid-based quantum systems, superconducting quantum circuits, magnetism, spintronics, correlated electron systems | |
| Prof. Michael Hartmann | FAU-PH | superconducting quantum circuits, quantum algorithms, nanomechanical systems, quantum optics | |
| Prof. Albert Heuberger | FhG-IIS | integrated electronics, applied quantum technologies, high-performance signal processing platform, quantum algorithms for applications, cloud and infrastructure | |
| Prof. Alexander Högele | LMU-PH | quantum nano-systems, quantum dots, quantum optics | |
| Prof. Alexander Holleitner | TUM-PH / WSI | single-atom circuits, topological materials and electronics, excitonic many-body states including Bose-Einstein condensates, femtosecond on-chip electronics | |
| Dr. Hans Hübl | TUM-PH / WMI | solid-based quantum systems, superconducting quantum circuits, magnetism, spintronics | |
| Prof. Christian Jirauschek | TUM-CIT | theoretical and computational photonics, nanoelectronics, nano-optoelectronics | |
| Prof. Michael Knap | TUM-PH | strongly correlated quantum many-body systems, non-equilibrium quantum dynamics, ultracold quantum gases | |
| Prof. Johannes Knolle | TUM-PH | strongly correlated quantum many-body systems, quantum phases of matter, quantum spin liquid | |
| Prof. Robert König | TUM-MA | quantum information theory, quantum fault-tolerance, quantum algorithms | |
| Prof. Dieter Kranzlmüller | LMU-IN | high-performance computing, quantum computing | |
| Prof. Christoph Kutter | FhG-EMFT / UniBW | silicon-based semiconductor technology, quantum computing | |
| Prof. Claudia Linnhoff-Popien | LMU-IN | quantum computing, machine learning | |
| PD Dr. habil. Jeanette Miriam Lorenz | FhG-IKS | dependable quantum computing, quantum machine learning, dependable quantum applications | |
| Dr. Jürgen Lorenz | FhG-IISB | semiconductor device simulation, semiconductor technology simulation, modeling and artificial intelligence | |
| Prof. Florian Marquardt | MPL, FAU-PH | cavity optomechanics and nanomechanics, quantum information processing, quantum many-body physics, machine learning for physics | |
| Dr. Achim Marx | TUM-PH / WMI | solid-based quantum systems, superconducting quantum circuits, nanomechanical systems | |
| Prof. Christian Mendl | TUM-IN | strongly correlated quantum many-body systems, quantum computing, transport properties of physical systems | |
| Prof. Roland Nagy | FAU-EEI | RF microelectronics, system design, integrated electronics, applied quantum technologies | |
| Dr. Janis Noetzel | TUM-CIT | quantum information theory, quantum networks, quantum signal processing | |
| Prof. Lode Pollet | LMU-PH | strongly correlated quantum many-body systems, cold atoms in optical lattices, quantum Monte Carlo methods | |
| Prof. Frank Pollmann | TUM-PH | strongly correlated quantum many-body systems, topological phases of matter, tensor networks | |
| Dr. Andreas Reiserer | TUM-PH / MPQ | quantum networks, distributed quantum information processing, spin qubits | |
| Dr. Christian Schilling | LMU-PH | quantum information theory, quantum chemistry, strongly correlated quantum many-body systems | |
| Prof. Kai Phillip Schmidt | FAU-PH | condensed matter physics, quantum optics, quantum information, topological and frustrated magnetism | |
| Prof. Ulrich Schollwöck | LMU-PH | strongly correlated quantum many-body systems, cold atoms in optical lattices, tensor networks | |
| Dr. Thomas Schulte-Herbrüggen | TUM-CH | nuclear magnetic resonance, magnetic resonance imaging, quantum computing | |
| Prof. Martin Schulz | TUM-IN | high-performance computing, quantum computing | |
| Prof. Helmut Seidl | TUM-IN | automatic program analysis, programming languages, semi-structured data, tree-automata | |
| Prof. Marc Tornow | TUM-CIT | molecular electronics, functional electronic materials, resistive switching devices, nanopores | |
| Prof. Jan von Delft | LMU-PH | strongly correlated quantum many-body systems, tensor networks, functional renormalization group | |
| Prof. Martin Vossiek | FAU-EEI | RF microelectronics, system design, integrated electronics, applied quantum technologies | |
| Prof. Robert Weigel | FAU-EEI | RF microelectronics, system design, integrated electronics, applied quantum technologies | |
| Prof. Harald Weinfurter | LMU-PH | quantum information, quantum optics | |
| Prof. Robert Wille | TUM-CIT | quantum computing, microfluidics, conventional computing | |
| Dr. Johannes Zeiher | MPQ | quantum simulator, cold atoms in optical lattices, rydberg atoms |