The institute currently has eight departments.
Electronic Structure Theory Led by
Ali Alavi, the Department of Electronic Structure Theory is concerned with the development of
ab initio methods for treating
correlated electronic systems, using
Quantum Monte Carlo, quantum chemical and many-body methodologies. Ab initio methods (including density functional theory) will be applied to problems of interest in heterogeneous catalysis, surface chemistry, electrochemistry, and photochemistry.
Solid State Spectroscopy The Department of Solid State Spectroscopy is headed by Bernhard Keimer.
Collective quantum phenomena in highly correlated electronic materials are studied by spectroscopic and scattering techniques. Topics of particular current interest include the interplay between charge, orbital, and spin degrees of freedom in transition metal oxides, the mechanism of high-temperature superconductivity, and the control of electronic phase behavior in metal-oxide superlattices. The department also develops new spectroscopic methods such as high-resolution neutron spectroscopy and spectral ellipsometry.
Nanoscale Science Research efforts in the Department of Nanoscale Science, directed by Klaus Kern, are centered on nanometer-scale science and technology. The aim of the interdisciplinary research at the interface between physics, chemistry and biology is to gain control of materials at the atomic and molecular level, enabling the design of systems and devices with properties determined by quantum behavior on one hand and approaching functionalities of living matter on the other hand.
Nanochemistry The Lotsch department employs modern techniques of nanochemistry and combines them with classical methods of solid-state synthesis to develop materials with complex property profiles, including two-dimensional systems and layered heterostructures, porous frameworks, photonic nanostructures, and solid electrolytes for applications in (photo)catalysis, sensing, and solid-state batteries.
Physical Chemistry of Solids Under Joachim Maier, the Department of Physical Chemistry of Solids is concerned with
electrochemistry and
ion transport. Emphasis is laid on ion conductors (such as inorganic or organic proton, metal ion and oxygen ion conductors) and mixed conductors (typically perovskites). The research ranges from the exploration of basic mechanisms to the design of materials for electrochemical applications (batteries, fuel cells, sensors). Of special significance is the scientific foundation of the field Nanoionics.
Solid State Quantum Electronics Induced by quantum mechanical phenomena, heterostructures grown from complex materials offer a fascinating potential to create novel electron systems. Many have outstanding properties that are not otherwise found in nature. The design, growth, and exploration of such electron systems are at the focus of the Department of Solid State Quantum Electronics spearheaded by
Klaus von Klitzing. The group is led by
Jochen Mannhart.
Quantum Many-Body Theory Directed by Walter Metzner, Electronic properties of solids are analyzed and computed in the Department of Quantum Many-Body Theory with a main emphasis on systems where electronic correlations play a crucial role, such as
cuprates,
manganites and other
transition metal oxides. Besides symmetry-breaking phase transitions leading to
magnetism, orbital and charge order, or
superconductivity, correlations can also cause electron localization and many other striking many-body effects not described by the independent electron approximation. ===
Quantum Materials=== Entanglement of electrons in solids, in combination with details of the crystal lattice structure, produce a surprisingly rich variety of electronic phases, that are liquid, liquid-crystal and crystalline states of the charge and spin degrees of freedom. These complex electronic phases and the subtle competition among them very often give rise to novel functionality. The Department of Quantum Materials, led by Hidenori Takagi, is studying these interesting novel phases in transition metal oxides and related compounds where the narrow d-bands, which give rise to strong electron correlations, in combination with the rich chemistry of such materials provide excellent opportunities for new discoveries. == Scientific members ==