Network: Spin and charge in electrochemically doped oxides

 
French-german network program
Programme de Recherche en Reseaux (P2R)

Spin and charge in electrochemically doped oxides

Partners       Our Aims       People       PhD students       Publications

Network Partners

• Laboratoire de Physico-Chimie de l'Etat Solide, Orsay, France
  Synthesis of single crystals for electrochemical doping

• Laboratoire de Réactivité et de Chimie des Solides, Amiens, France
  Electrochemical doping of transition metal oxides
• Laboratoire National des Champs Magnétiques Pulsés, Toulouse, France
  Pulsed field studies of electrochemically doped transition metal oxides
• Leibniz Institute for Solid State and Materials Research (IFW), Dresden, Germany
  Thermodynamic, magnetic and spectroscopic studies of electrochemically doped transition metal oxides
• Institute for Metal Physics and Nuclear Solid State Physics and Institute for Theoretical Physics, Braunschweig, Germany
  Applying local probes and numerical calculations to study electrochemically doped transition metal oxides

Our Aims

The physics of transition metal oxides is one of the most fascinating and very important topics in contemporary condensed matter research. The physical properties of these systems are controlled by the combination and competition of several degrees of freedom, in particular the charge, the spin and the orbital state of the electrons. This interplay gives rise to a rich variety of ground states. Technologically important are, e.g., the high temperature superconducting cuprates and the manganites with colossal magnetoresistance.

One important parameter responsible for the physical properties in these systems is the density of charge carriers which determines the oxidization state of the transition metal. In most experimental studies reported to date the charge carrier density is adjusted either by a partial substition of the cations via a solid state reaction or by a modification of the oxygen content via a thermal treatment under a controlled oxygen athmosphere. Therefore the physics in these systems is considerably influenced by steric effects and disorder.

The central objective of this research program is the study of transition metal oxides in which the charge carrier density is adjusted and controlled via electrochemistry. This method is based on the extraction and insertion of light alcaline metal ions in the crystal lattice which directly changes the valence of the transition metal. It allows the preparation of extraordinary oxidization states with new physical properties. Lithium based transition metal oxides are also used as state-of-the-art rechargable power sources. Therefore a deep understanding of the structural and electronic properties of these systems is also of high technological interest.