Covers the basics of supramolecular chemistry, including self-assembly processes and molecular interactions such as hydrogen bonding and cation-π interactions.
Delves into supramolecular chemistry, focusing on molecular machines and motors, exploring design principles and experimental support for controlled motion.
Explores self-organized growth at surfaces and covers instrumentation, destructive exposure, manipulation with SIM, nanostructures, and thin film growth.
Explores the transition of knots from practical applications to mathematical theory, covering equilibrium, tension analysis, ideal shapes, DNA mechanics, and pressure distributions.
Explores recent developments in metallacycles, molecular squares, cages, and helicates via coordination, highlighting sequence-selective peptide recognition and self-recognition in helicates.
Explores the self-assembly of heterobimetallic systems to create robust duplexes in water, emphasizing the importance of synthetic H-bond systems for materials fabrication.
Explores the F-type ATP Synthase, a molecular machine crucial for energy production in cells, covering its structure, function, and energy production mechanisms.
Explores methods for probe immobilization on surfaces, including self-assembly and peptide bonds, discussing the role of hydrophobic interactions and kinetic models.
