The central topic of this Research Unit is the exploration and identification of physical scenarios with one-dimensional properties under explicit consideration of 2D and 3D coupling, their control and their manipulation. It was chosen for obvious reasons: The attractive special properties of ideal one-dimensional (1D) electronic systems such as quantization of conductance, charge-density waves (CDWs), and Luttinger-liquid behav- ior, coupled with a variety of instabilities with a wealth of associated phase transitions, are experimentally only observable in systems that interact in two (2D) or three (3D) dimensions. Apart from stabilization of 1D properties at T >0, controlled modification of these couplings allows tuning and changes also of the 1D behavior. In this way we try to obtain deeper insight into this highly interesting field by close collaboration between experimental and theoretical groups. Metallic atomic wires, consisting of self-organized atomic chains of Au, Pt, In or Pb grown on Si or Ge surfaces, as well as silicide wires, formed with rare earth elements or transition metals, are prototype 1D systems, on which we concentrate. Based on the gathered experience, we will continue to correlate studies of structure and phase transi- tions in the wires and their electronic structure with electronic transport, single particle and collective excitations as well as with their dynamics. In this new funding period, a focus will be put on the controlled variation of coupling between wires, coupling to the underlying substrate and to the 3D embedding material. For this purpose, we plan to ma- nipulate charge densities, long range order and local structure by adsorption of atoms and molecules, variation of step densities, step orientations and substrates. Further emphasis will be given to the unexpected large degree of spin order in these systems, its stability and coupling to other parameters. Furthermore phonon and electron dynamics will play an important role as well as photoinduced phase transitions. The already well established close collaboration between experiment and theory as well as the combination of various experimental methods applied to identical systems will be continued and intensified in order to explore this field comprehensively.

DFG Programme Research Units

• Atomic structure and electronic properties of silicide nanowires (Applicants Dähne, Mario ;  Wollschläger, Joachim )
• Coordination Project (Applicant Pfnür, Herbert )
• Embedded one-dimensional electron-phonon systems (Applicant Jeckelmann, Eric )
• Ground- and excited-state properties of substrate-supported nanowires calculated from first principles (Applicants Sanna, Simone ;  Schmidt, Wolf Gero ;  Wippermann, Stefan Martin )
• Spectral electronic properties of noble metal nanowires with controlled architectures (Applicant Schäfer, Jörg )
• Spin-resolved electonic properties of strongly correlated one-dimensional systems (Applicant Bode, Matthias )
• Surface optical spectroscopy of phonon and electron excitations in quasi one-dimensional metallic nanostructures (Applicants Esser, Norbert ;  Pucci, Annemarie )
• Time-resolved diffraction of photo-induced phase transitions in 1D metal wires on semiconductor surfaces (Applicant Horn-von Hoegen, Michael )
• Time-resolved spectroscopy of photo-induced transitions and electronic excitations in quasi-1D metal wires on semiconductors (Applicants Bovensiepen, Uwe ;  Wolf, Martin )
• Transport and collective excitations in metallic wires (Applicant Tegenkamp, Christoph )

Spokesperson Professor Dr. Herbert Pfnür