Out-of-Equilibrium (Supra)molecular Systems and Materials

Nicolas Giuseppone is Distinguished Professor (Classe Exceptionnelle) at the University of Strasbourg. He received his PhD in asymmetric catalysis (laboratory of Professor H.B. Kagan), performed a post-doctoral research in total synthesis (laboratory of Professor K.C. Nicolaou), and entered the field of supramolecular chemistry as an Assistant Professor (laboratory of Professor J.-M. Lehn). In 2008 he started his own research group and became Associate Professor. Since 2016, he is full professor in Strasbourg. Andreas Walther is a Professor for Functional Polymers at the Institute for Macromolecular Chemistry at the University of Freiburg (Germany). His research interests concentrate on developing and understanding hierarchical self-assembly concepts inside and outside equilibrium, and on using them to create active, adaptive and autonomous bioinspired material systems. He graduated from Bayreuth University in Germany in 2008 with a PhD focusing on the self- assembly behavior and applications of Janus particles and other soft, complex colloids. After a post-doctoral stay with a focus on biomimetic hybrid materials at Aalto University (Helsinki, Finland), he returned to Germany in 2011, and established his independent research group at the DWI - Leibniz Institute for Interactive Materials in Aachen. In 2016 he was appointed to his present position in Freiburg.

Out-of-equilibrium (supra)molecular systems and materials: An introduction
Learning from embryo development to engineer self-organizing materials
From clocks to synchrony: the design of bioinspired self-regulation in chemical systems
De novo design of chemical reaction networks and oscillators and their relation to emergent properties
Kinetically controlled supramolecular polymerization
Chemically fueled, transient supramolecular polymers
Design of chemical fuel driven self-assembly processes
Dynamic combinatorial chemistry out-of-equilibrium
Controlling self-assembly of nanoparticles using light
Photoswitchable components to drive molecular systems away from global thermodynamic minimum by light.
Out-of-equilibrium threaded and interlocked molecular structures
Light-driven rotary molecular motors for out-of-equilibrium systems
Design of active nanosystems incorporating biomolecular motors
Index