Your search keyword '"Kiefer, Henrik"' showing total 2 results

1. The role of memory-dependent friction and solvent viscosity in isomerization kinetics in viscogenic media.

Author

Dalton, Benjamin A., Kiefer, Henrik, and Netz, Roland R.

Subjects

ISOMERIZATION kinetics, GIBBS' energy diagram, FRICTION, INTERNAL friction, MOLECULAR dynamics, SOLVENTS

Abstract

Molecular isomerization kinetics in liquid solvent depends on a complex interplay between the solvent friction acting on the molecule, internal dissipation effects (also known as internal friction), the viscosity of the solvent, and the dihedral free energy profile. Due to the absence of accurate techniques to directly evaluate isomerization friction, it has not been possible to explore these relationships in full. By combining extensive molecular dynamics simulations with friction memory-kernel extraction techniques we consider a variety of small, isomerising molecules under a range of different viscogenic conditions and directly evaluate the viscosity dependence of the friction acting on a rotating dihedral. We reveal that the influence of different viscogenic media on isomerization kinetics can be dramatically different, even when measured at the same viscosity. This is due to the dynamic solute-solvent coupling, mediated by time-dependent friction memory kernels. We also show that deviations from the linear dependence of isomerization rates on solvent viscosity, which are often simply attributed to internal friction effects, are due to the simultaneous violation of two fundamental relationships: the Stokes-Einstein relation and the overdamped Kramers prediction for the barrier-crossing rate, both of which require explicit knowledge of friction. Molecular isomerization in solution is dependent on coupling of solute and solvent via memory-dependent friction. Here, by applying memory kernel extraction to molecular dynamics simulations, the authors demonstrate the role of friction in determining isomerization kinetics. [ABSTRACT FROM AUTHOR]

Published

2024

2. A synthetic tubular molecular transport system.

Author

Stömmer, Pierre, Kiefer, Henrik, Kopperger, Enzo, Honemann, Maximilian N., Kube, Massimo, Simmel, Friedrich C., Netz, Roland R., and Dietz, Hendrik

Subjects

DNA folding, HOLLOW fibers, MOLECULAR motor proteins, TRANSMISSION electron microscopy, FLUORESCENCE microscopy, FREE surfaces

Abstract

Creating artificial macromolecular transport systems that can support the movement of molecules along defined routes is a key goal of nanotechnology. Here, we report the bottom-up construction of a macromolecular transport system in which molecular pistons diffusively move through micrometer-long, hollow filaments. The pistons can cover micrometer distances in fractions of seconds. We build the system using multi-layer DNA origami and analyze the structures of the components using transmission electron microscopy. We study the motion of the pistons along the tubes using single-molecule fluorescence microscopy and perform Langevin simulations to reveal details of the free energy surface that directs the motions of the pistons. The tubular transport system achieves diffusivities and displacement ranges known from natural molecular motors and realizes mobility improvements over five orders of magnitude compared to previous artificial random walker designs. Electric fields can also be employed to actively pull the pistons along the filaments, thereby realizing a nanoscale electric rail system. Our system presents a platform for artificial motors that move autonomously driven by chemical fuels and for performing nanotribology studies, and it could form a basis for future molecular transportation networks. DNA origami can be used to control the movement of nanoscale assemblies. Here the authors construct multiple-micrometer-long hollow DNA filaments through which DNA pistons move with micrometer-per-second speeds. [ABSTRACT FROM AUTHOR]

Published

2021