Dr. Manfred Wagner

Manfred Wagner obtained in 1988 his diploma degree in chemistry from the University of Mainz in the group of Prof. K. Müllen and completed his PhD thesis “Repetitive Diels-Alder reaction to synthesize band structures” in 1993 at the MPI-P under the supervision of K. Müllen. Since 1990 he is responsible for the high resolution NMR department of the Max-Planck-Institute for Polymer Research. His main topics beside the investigation of the microstructure of marco-molecules (e.g. polymers or biomolecules) are all kind of active nuclei like 7Li, 11B, 15N, 19F, 27Al, 29Si and 31P nuclei (and many other nuclei) and their physical and chemical properties/interactions over the last 29 years. He leads the Nanodiamond (ND) group since 2016 to develop new synthetic strategies for nanodiamonds particle with active center in the crystal via HPHT (High Pressure, High Temperature). The synthesis with defect-defined NDs with sizes below 10 nm and controlled positioning of the defect atom(s) has been impossible to date. Their unique features besides the chemical and mechanical stability like photoluminescence, magnetic and electrical properties make it possible to combine attractive qualities such as NIR emission, hyperpolarization and magnetic sensing.

Research Interests

Materials such as polymers or biomolecules are complex chemical, physical, and biological systems that are rarely fully understood in their entirety. For all types of interactions in different length and time scales, a variety of experimental methods are used to generate a greater understanding. One of our main interests is the combination of different methods to understand more about the micro- and macroscopic properties of materials. Which driving force is responsible for the reaction and which three-dimensional structure is necessary to reach the goal? The interaction of physical properties and the chemical functions in structures are very often the key to understanding and for this we combine a variety of methods such as AFM, TEM, FCS, DLS, XPS, MALIDI-TOF, TOF-SIMS and many more. Together with the various experts in our institutes and partners in other faculties, we seek to understand the chemical and physical properties in nano- or micromaterials in any length and time scale to use this knowledge in biological systems.

Selected Publications

Journal Article (146)

Journal Article
Barent, R. D.; Wagner, M.; Frey, H.: Geometric requirements for living anionic polymerization: polymerization of rotationally constrained 1,3-dienes. Polymer Chemistry 13 (38), pp. 5478 - 5485 (2022)
Journal Article
Kutus, B.; Wagner, K.; Wagner, M.; Hunger, J.: Ion-pairing equilibria and kinetics of dimethyl phosphate: A model for counter-ion binding to the phosphate backbone of nucleic acids. Journal of Molecular Liquids 363, 119868 (2022)
Journal Article
Yu, H.; Wang, S.; Huang, J.; Fu, Y.; Wagner, M.; Weil, T.; Zhong, F.; Zhao, W.; Wu, Y.: Light-Controlled Traceless Protein Labeling via Decaging Thio-o-naphthoquinone Methide Chemistry. Organic Letters 24 (37), pp. 6816 - 682 (2022)
Journal Article
Zhou, Z.; Maxeiner, K.; Moscariello, P.; Xiang, S.; Wu, Y.; Ren, Y.; Whitfield, C.; Xu, L.; Kaltbeitzel, A.; Han, S. et al.; Mücke, D.; Qi, H.; Wagner, M.; Kaiser, U.; Landfester, K.; Lieberwirth, I.; Ng, D. Y. W.; Weil, T.: In Situ Assembly of Platinum(II)-Metallopeptide Nanostructures Disrupts Energy Homeostasis and Cellular Metabolism. Journal of the American Chemical Society 144 (27), pp. 12219 - 12228 (2022)
Journal Article
Hahn, C.; Wagner, M.; Müller, A. H. E.; Frey, H.: MyrDOL, a Protected Dihydroxyfunctional Diene Monomer Derived from beta-Myrcene: Functional Polydienes from Renewable Resources via Anionic Polymerization. Macromolecules 55 (10), pp. 4046 - 4055 (2022)
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