Keimer's department > Research

Our research projects

Unconventional superconductivity

The microscopic description of superconductivity in complex materials such as layered cuprates, cobaltates, or the recently discovered iron pnictides, is one of the most important challenges in current solid-state physics. Our group uses high-quality single crystals and state-of-the-art experimental methods to derive accurate spectra of spin and charge excitations in these materials. Such data are essential to motivate and test new theoretical concepts for the correlated electron systems that support unconventional superconductivity.

Low-dimensional magnetism

The discovery of high-temperature superconductivity has stimulated a tremendous upsurge of interest in the quantitative understanding of low-dimensional quantum magnets. Experiments performed in our group elucidate the magnetic structure and dynamics of one- and two-dimensional magnets and their influence on charge transport. Novel compounds synthesized by chemists at our institute are of particular importance.

Orbital degeneracy

The exceptionally rich phase behavior observed in transition metal oxides originates in a competition between many-body states with different spin, orbital, and charge ordering patterns. Work in our group seeks to unravel the microscopic mechanisms underlying this competition. To this end, spectroscopic data on orbitally degenerate transition metal oxides obtained in our group are analyzed and interpreted in close collaboration with theorists.

Oxide heterostructures

Carefully controlled interfaces between two materials can give rise to novel physical phenomena and functionalities not exhibited by either of the constituent materials alone. Modern synthesis methods have yielded high-quality heterostructures and superlattices of oxide materials with competing quantum many-body states. In order to explore new correlation-driven interface phenomena, our group seeks to understand and manipulate the spin and orbital polarization at oxide interfaces (“orbital engineering”).
Spectroscopic tools

Spectral ellipsometry

Spectral ellipsometry measures the real and imaginary parts of the dielectric function of solids with significantly higher accuracy and reproducibility than regular reflection spectroscopy.

Neutron spin-echo spectroscopy

Neutron resonant spin-echo spec­tros­copy, in combination with triple-axis spectroscopy, affords the de­ter­mi­nation of lifetimes of dispersive excita­tions over the entire Brillouin zone with μeV resolution.

Raman scattering

Raman scattering yields information about lattice dynamical, charge, and orbital excitations that is often comple­mentary to information obtained by infrared and neutron spectroscopies.

Resonant X-ray diffraction

Resonant diffraction and inelastic scat­tering with x-ray photons near the L-absorption edge of transition metal ions are very sensitive probes for mag­netic and orbital ordering phenomena.