Soft Nanoscience
Mimicking functional natural materials
Soft materials have a modular structure and the ability to repair themselves if damaged. These natural materials are self-organizing and characterized by a wide range of properties which inert, synthetic materials such as steel or aluminum do not have. Control over these natural functions in synthetic, biomimetic nanosystems is key to the nanosciences of the future.
Research fields in soft nanoscience
The SoN research program aims to investigate and understand the fundamental preparation processes of biomimetic functional natural materials according to the molecular “bottom-up” fabrication principle. Our primary focus is on 3D nanomaterials and (nano)containers. We aim to integrate experimental findings with theoretical models in order to understand both the molecular level and the nonlinear processes of self-assembly.
Following are the research fields and relevant projects carried out at SoN:
Self-assembly and dynamics
Nanostructured surfaces are versatile platforms for attaching locally functional molecules using various bottom-up processes. Locally functional molecules are often attached via self-assembly processes, either on planar surfaces or in zeolite cages.
SoN researchers investigate the basic processes underlying self-assembly and its kinetics, both experimentally and theoretically. Self-assembly also plays an important role in the functionalization of surfaces with chiral and helical molecules, which act as sources for spin-oriented electrons in future molecular spintronic devices. Using AFM and localization microscopy (STORM), researchers study self-assembled ensembles and domains in cell membranes. Also of interest is the dimensionality of the surrounding, whether 2D or 3D, where the electron interaction between various constituents is studied.
Projects
- Cellular membrane and lipid dynamics- Prof. Volker Gerke
- Electron transfer in functional organic films- Prof. Helmut Zacharias
- Evolution of surface geometries by self-assembly- PD Dr. Svetlana Gurevich
- Molecular self-assembly- Prof. Bart Jan Ravoo
- Multiscale simulation of self-replicating systems- Prof. Nikos Doltsinis
- Nanostructured biochemical surfaces- Adjunct Prof. Lifeng Chi
- Polyelectrolyte Self-Assembly: Multilayers, Coacervates and Hydrogels- Prof. Monika Schönhoff
- Self-organisation of membrane domains- Prof. Roland Wedlich-Söldner
- Simulation of self-organisation effects- Prof. Andreas Heuer
- Zeolites – nanoporous materials with tailored reaction environments- PD Dr. Hubert Koller
Nanotools
SoN has state-of-the art nanoanalytic and nanostructuring instruments, including an AFM and a STM, He ion microscopy, a ToF-SIMS, and a Fourier-transform tip-enhanced SNOM in the IR (for details see the MNF pages). Also available for use are He and Ga ion beam machines for top-down structuring. With our dip pen lithography instruments it is possible to use bottom-up techniques to grow advanced functional nanostructures.
Our infrastructure and methodologies are continuously updated to satisfy future needs and enable new insights into nanosystems. We also apply methodologies for integrating functional films into optoelectronic devices on a chip, e.g. for optical quantum operations.
Projects
- Cellular light nanoscopy- Prof. Jürgen Klingauf
- Constructive lithography for biomimetic surfaces- Prof. Harald Fuchs
- Engineering quantum nano-systems- Prof. Ursula Wurstbauer
- Electron transfer in functional organic films- Prof. Helmut Zacharias
- Functional surface nanostructures- Prof. Gerhard Wilde
- Integrated quantum technology- Prof. Carsten Schuck
- Nanoanalysis with ToF-SIMS/Laser-SNMS- Prof. Heinrich Arlinghaus
- Nanophotonics and single photon detection- Prof. Wolfram Pernice
- Nanostructured biochemical surfaces- Adjunct Prof. Lifeng Chi
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Structured light imaging at the nanoscale- Dr. Eileen Otte
Synthesis
The synthesis of novel molecules with novel functions is an important endeavor. Novel stereoselective synthesis not only leads to carbenes and ionic metal-doped DNA, but also to polymeric radicals and addressable and switchable moieties on nanoparticles. Furthermore, on-surface reactions provide a new environment that can generate products which cannot be synthesized in conventional liquid-phase reactions. SoN researchers treat electronic properties of new molecules at various levels of precision using theoretical chemistry and ultrafast spectroscopy.
Projects
- Functionalized nanoparticles- Prof. Frank Glorius
- On-surface reactions in ultrahigh vacuum- Prof. Armido Studer
- Photofunctional nanomaterials for optoelectronics and theranostics- Prof. Christian Strassert
- Surface assisted chemical reactions- Prof. Harald Fuchs
- Synthetic nucleic acids- Prof. Jens Müller
Responsive systems
Functional surface coatings such as polymer brushes or gels have the potential to facilitate the adhesion of molecules and nanoparticles. Researchers at SoN develop strategies for modulating surface coatings with an external trigger in a simple form— with light stimulation. Using multiscale simulations, our researchers aim to gain insight from a theoretical point of view: the properties of functional, bioactive films or nanoparticles can influence the growth of cells and even molecular defined leucocytes, serving as model systems of synaptic activity and inflammatory reactions.
Projects
- Molecular Control of Soft Matter Interfaces and Materials- Prof. Björn Braunschweig
- Multiscale simulation of self-replicating systems- Prof. Nikos Doltsinis
- Responsive nanocontainers, gels and surface coatings- Prof. Bart Jan Ravoo
- Theory of functional nanosystems- Prof. Johannes Neugebauer
- Thermoresponsive polymer microgels- Prof. Monika Schönhoff
Bioactive hybrid interfaces
In this field SoN researchers specifically design and synthesize functional organic molecules to interact with various biosystems. In a first and simple step, we investigate optimized combinations for photoactivation. Some of our more complex schemes involve porous nanoparticles with functionalized bioactive pores, often with Janus density gradients between two active moieties. Nanoscopic approaches at chirally modified surfaces reveal first steps of cell – material interactions. Our research benefits from a general theoretical approach which addresses questions of active motion of bioactive particles through their environment.
Projects
- Analysis of innate immunity at the nanoscale- Dr. Kristina Riehemann
- Cellular light nanoscopy- Prof. Jürgen Klingauf
- Decoding the molecular basis of mental illness- Prof. Michael Ziller
- High Resolution Cryo Electron Microscopy- Prof. Gatsogiannis
- Immuno-functional nanoparticles- Prof. Johannes Roth
- Light controlled synthetic biology- Prof. Seraphine Wegner
- Theory of active soft matter- Jun. Prof. Raphael Wittkowski