The field of nanoscience has significantly matured during the last decade. Perspectives for applications based on nanostructures have emerged which rely crucially on a precise control of the interaction between nanosystems or the influence of external fields. Our Collaborative Research Centre approaching the topic from the physics and the chemistry perspective has contributed significantly to the progress in nanoscience by developing control mechanisms for individual nanosystems. We have shown that achieving control by structural, optical or electric means is a promising route to an advanced understanding of mechanical, electronic, and magnetic properties of nanosystems. Our research program is organized around these topics. The first area covers Structural and mechanical properties and here the investigations have focused on coherent mechanical excitations of membranes and beams controlled by electromagnetic fields. One main finding is the origin of mechanical damping in nanomembranes and the coherent control of a nanobeam. In future, this area will extend the research towards control of heat transport by temperature gradients. In the second research area on Optical and electronic properties the main goal is to use the potential of optical control of nanosystems. An unprecedented level of control was achieved experimentally by two-color excitations of molecules and theoretically of spin-qubit candidates. Further major progress concerned stability of colloidal quantum dots, their control on ultrafast time scales and in magnetic fields as well as direct detection of the photonic vacuum. In future, this area will expand to an ultrafast control of the coupling between a tunnel current and photons. The third project area, Electronic and magnetic transport properties, has elaborated on the control of electrons in single molecular junctions or quantum point contacts and the magnetization in nanostructures. As highlights we have shown how to control single spins in molecules, single electrons by voltage pulses, vibrational modes by current, and domain walls by thermal gradients. In the future, we will continue this research concentrating on the most promising aspects. The last funding period will be devoted to fine-tuning control schemes like electrical and optical field effects on mechanical and magnetic nanosystems, molecules and semiconductor quantum dots. Based on the insights of the previous funding periods we will extend our scope to topics such as ultrafast manipulation of electronic tunneling currents and engineered heat flow in nanocontacts.

DFG Programme Collaborative Research Centres

• A01 - Optical control of phonons and their dissipation in nanostructures (Project Head Dekorsy, Thomas )
• A02 - Laser-induced mechanical excitation of nanostructures (Project Heads Boneberg, Johannes ;  Leiderer, Paul )
• A03 - Control of vibrational modes and dissipation in nanomechanical resonators (Project Heads Dekorsy, Thomas ;  Erbe, Artur Philipp Nikolaus ;  Leiderer, Paul ;  Scheer, Elke )
• A06 - Structural control of nanoscale model system (Project Head Nielaba, Peter )
• A07 - Dielectric control of high Q nanomechanical resonators (Project Head Weig, Eva M. )
• A08 - Vibrational properties and phonon transport of nanobridges (Project Head Pauly, Fabian )
• B01 - Control of nanostructures by terahertz field (Project Head Dekorsy, Thomas )
• B02 - Ultrafast quantum control of single electrons and photons in mesoscopic systems (Project Heads Bratschitsch, Rudolf ;  Leitenstorfer, Alfred ;  Mecking, Stefan ;  Seletskiy, Ph.D., Denis )
• B03 - Controlling fluorescence emission of single molecules by vibrational excitation (Project Head Zumbusch, Andreas )
• B04 - Control of the properties of clusters using external fields (Project Head Ganteför, Gerd )
• B05 - Terahertz quantum optics with semiconductor nanostructures (Project Heads Huber, Rupert ;  Leitenstorfer, Alfred )
• B06 - Coherent optical spin and charge control in nanostructures (Project Head Burkard, Guido )
• B08 - Electron transport in nanostructures controlled by phase-locked single-cycle light pulses (Project Heads Brida, Daniele ;  Leitenstorfer, Alfred )
• C02 - Controlling the electronic transport through molecular systems (Project Heads Groth, Ulrich ;  Huhn, Thomas ;  Scheer, Elke )
• C03 - Time-dependent transport in correlated electron nanostructures (Project Heads Belzig, Wolfgang ;  Rastelli, Ph.D., Gianluca )
• C04 - Controlling the spin and electronic interaction in atomic and molecular contacts (Project Heads Kern, Klaus ;  Schlickum, Uta ;  Ternes, Markus ;  Wahl, Peter )
• C05 - Molecular magnets: single-molecule spectroscopy and electronic transport (Project Heads Fonin, Mikhail ;  Groth, Ulrich )
• C06 - Spin currents in magnetic nanostructures (Project Heads Kläui, Mathias ;  Rüdiger, Ulrich )
• C07 - Interaction of spin-currents with magnetic domain walls (Project Heads Kläui, Mathias ;  Nielaba, Peter )
• C08 - Controlling quantum systems by electrical current (Project Head Belzig, Wolfgang )
• C10 - Control of magnetic nanostructures by spin currents and thermal gradients (Project Heads Hinzke, Denise ;  Nowak, Ulrich )
• C11 - Control of magnetic domains and domain walls by thermal gradients (Project Heads Boneberg, Johannes ;  Fonin, Mikhail )
• C13 - Mechanical control of charge transport through nanostructures (Project Head Pauly, Fabian )
• C14 - Local spectroscopy of multi-spin molecules: valency distributions and magnetic properties (Project Heads Fonin, Mikhail ;  Winter, Rainer )
• MGK - Integrated Research Training Group Nano (Project Heads Belzig, Wolfgang ;  Scheer, Elke )
• Z - Central tasks (Project Heads Belzig, Wolfgang ;  Scheer, Elke )

Applicant Institution Universität Konstanz

Participating Institution Max-Planck-Institut für Festkörperforschung (MPI-FKF)

Spokespersons Professor Dr. Wolfgang Belzig, since 1/2012; Professorin Dr. Elke Scheer, until 1/2012