Switching is an elementary step in information technology, most engineering functions, and machines. Top-down miniaturization of the switching units in electronic circuits triggered an unprecedented technological development that changed our life in many aspects. Beyond increasing the power of computers, miniaturization of other technological functions will lead to higher efficiencies as well, and moreover, it will open novel applications in medicine, energy, environment, and materials science. Molecular switches are at the focus of research in our collaborative research centre. They offer the prospect of realising the ultimate limit of miniaturisation for the fabrication of functional molecular devices. Similar to its macroscopic analogue, a molecular switch is a molecule that can be reversibly shifted between two or more metastable states. Our molecular switches are controlled by non-invasive external stimuli (light, heat, electric fields, or electrons). In response to switching, the properties (optical, magnetic, electronic etc.) of the system change. Light is a particularly expedient trigger. It can be applied in different energies (wavelengths) and polarisations, with spatial and temporal control, and it leaves no trace if it is switched off. Molecular switching with light (photochromism) has already provided the basis to spectacular applications such as stimulated emission depletion (STED, RESOLFT) microscopy which allows super resolution imaging, or the construction of light switchable channel proteins for the non-invasive addressing of single brain neurons in optogenetics. The tip of a scanning tunnelling microscope (STM) is an extremely localised excitation source that enables detailed studies of single-molecules and their environment. Consequently, most of our molecular switches are triggered with light or the electric current of a STM tip. During the first and second funding periods a number of photochromic switches have been investigated, and new compounds have been synthesized. Improved azobenzene-type structures still proved to be most reliable. The chemistry of novel and modified switches has been developed and they are now used in several projects.A simple switch is not a machine, and switching alone is not sufficient to achieve a particular function. Therefore, switches have to be implemented in suitable environments that provide controlled interactions with the surrounding. Different environments require different scientific approaches and thus are a natural basis for the organisation of our collaborative research centre in three different fields of research projects: A. Solutions, B. Surfaces, C. Complex environments (including materials and biological systems).

DFG Programme Collaborative Research Centres

• A01 - Ultrafast Dynamics of Photoinduced Switching (Project Heads Hartke, Bernd ;  Renth, Falk ;  Temps, Friedrich )
• A02 - Light driven synthesis (Project Head Herges, Rainer )
• A03 - New spin crossover complexes for spin switching in solution and on surfaces (Project Heads Herges, Rainer ;  Tuczek, Felix )
• A04 - Light-driven proton pump (Project Heads Herges, Rainer ;  Lüning, Ulrich )
• A05 - Mechanics of switching single molecules in solution (Project Heads Beyer, Martin K. ;  Hartke, Bernd ;  Lüning, Ulrich )
• A06 - Switchable Contrast Agents for Magnetic Resonance Imaging (Project Heads Boretius, Susann ;  Herges, Rainer ;  Tuczek, Felix )
• A07 - Dynamics of H-Transfer Switches (Project Heads Hartke, Bernd ;  Lüning, Ulrich ;  Temps, Friedrich )
• A08 - Molecular Assemblers: Light Driven Molecular Machines for Synthesis (Project Head Herges, Rainer )
• B01 - Nano Switch driven by Localized Near-fields (Project Head Bauer, Michael )
• B02 - Directed molecular switching and transport on surfaces (Project Heads Herges, Rainer ;  Magnussen, Olaf )
• B03 - Spectroscopic investigation of surfaces functionalised by switchable molecules (Project Heads Kipp, Lutz ;  Rossnagel, Kai )
• B06 - STM/STS of Bistable Molecules (Project Head Berndt, Richard )
• B07 - Switching of Magnetic Single Molecules (Project Head Berndt, Richard )
• B08 - Spectroscopic investigations of switching properties Azobenzene-based monolayers on Gold and SiO2 surfaces (Project Heads Friedrichs, Gernot ;  Temps, Friedrich )
• B09 - Switching Adsorbate Layers Based on the Platform Concept (Project Heads Herges, Rainer ;  Magnussen, Olaf )
• B10 - Theory of imaging and switching the magnetic state of single molecules on surfaces (Project Head Heinze, Stefan )
• B11 - Switchable Cell Adhesion (Project Heads Lindhorst, Thisbe K. ;  Selhuber-Unkel, Christine )
• B12 - Active Plasmonics with Switchable Dielectric Materials (Project Head Bauer, Michael )
• B13 - Photoswitchable spin-crossover films on ferromagnetic substrates (Project Heads Rossnagel, Kai ;  Tuczek, Felix )
• C01 - Photoswitchable Metal-Polymer Nanocomposites (Project Heads Elbahri, Mady ;  Faupel, Franz ;  Strunskus, Thomas )
• C04 - Switchable molecules in porous membranes (Project Head Bensch, Wolfgang )
• C05 - Switchable, porous inorganic-organic hybrid compounds (Project Heads Herges, Rainer ;  Stock, Norbert )
• C07 - Magnetic switches based on nanoparticles of ferromagnetic shape memory alloys in a polymer matrix (Project Heads Faupel, Franz ;  Quandt, Eckhard )
• C09 - Multifunctional photoswitchable polymer fibers (Project Heads Elbahri, Mady ;  Müller, Martin ;  Strunskus, Thomas )
• C10 - Photoswitchable Adhesives (Project Heads Adelung, Rainer ;  Gorb, Stanislav N. ;  Staubitz, Anne )
• C11 - Switching the antifreeze activity of proteins (Project Heads Lindhorst, Thisbe K. ;  Sönnichsen, Frank )
• C12 - Photoswitchable Protein Kinase Inhibitors for Novel Anti-Cancer Applications (Project Head Peifer, Christian )
• C13 - Switching in molecular double layer membranes (Project Head Murphy, Bridget )
• C14 - Mechanophoric Composites (Project Heads Adelung, Rainer ;  Staubitz, Anne )
• MGK - Integrated Research Training Group (Project Heads Magnussen, Olaf ;  Tuczek, Felix )
• Z - Central Tasks (Project Head Herges, Rainer )
• Ö - Public Outreach (Project Heads Euler, Manfred ;  Parchmann, Ilka ;  Schwarzer, Stefan )

Applicant Institution Christian-Albrechts-Universität zu Kiel

Participating Institution IPN - Leibniz-Institut für die Pädagogik der Naturwissenschaften und Mathematik
an der Universität Kiel

Spokesperson Professor Dr. Rainer Herges