Development of an ultrafast low-energy electron diffraction setup

Gulde, Max

15 October 2014

No description available.

530

Physik (PPN621336750)

Electron Pulse

Surface Science

Structural Analysis

Superstructure Dynamics

Ultrathin Polymer Film

Graphene

PMMA

LEED

ULEED

polymer dynamics

Kinetics and dynamics of single biomolecules

Sturm, Sebastian

11 August 2016

This thesis contains several contributions to the theoretical description and interpretation of biophysical single-molecule measurements: (i) For semiflexible polymers, we derive an efficient formulation of their local transverse dynamics in terms of a Generalized Langevin Equation. The elastic and frictional properties of the polymer are condensed into a memory kernel that is a function of the polymer\''s length and stiffness, the level of backbone tension, the position of the force probe along the polymer backbone and the boundary conditions at the polymer ends. At short times, the memory kernel attains a universal limiting form that depends neither on the polymer length nor on the boundary conditions; we obtain analytical results that accurately describe this regime. We discuss how to quickly and reliably evaluate the memory kernel for arbitrary times using a spectral decomposition method, and use an extensive body of numerical data to obtain analytical approximations to the memory kernel that cover the complementary long-time limit wherein polymer friction can be subsumed under a renormalized drag coefficient. (ii) Based on a systematic nonequilibrium treatment of an overdamped, one-dimensional stochastic escape process driven by external force, we develop a theory of Dynamic Force Spectroscopy (DFS) that generalizes previously available DFS theories to the high loading rates realized in novel experimental assays and in computer simulations. (iii) Extrapolating to future DFS experiments that may operate at far higher time resolution than presently achievable, we discuss the fast nonequilibrium relaxation of a semiflexible linker after bond rupture. Based on a rigorous theory of tension propagation in semiflexible polymers, we predict the relaxation of force within the force actuator, show that this relaxation is dominated by linker contraction, and demonstrate quantitative agreement of our predictions with experimental data obtained by a collaborating experimentalist group.

info:eu-repo/classification/ddc/530

ddc:530

Theoretical Approaches to the Study of Fluctuation Phenomena in Various Polymeric Systems

Sharma, Rati

January 2013

The goal of this thesis has been to throw light on a selection of open problems in chemical and biological physics using the general principles of statistical mechanics. These problems are all broadly concerned with the role of fluctuations in the dynamics of macromolecular systems. More specifically, they are concerned with identifying the microscopic roots of a number of interesting and unusual effects, including fractional viscoelasticity, anomalous chain cyclization dynamics in crowded environments, subdifffusion in hair bundles, symmetries in the work distributions of stretched polymers, heterogeneities in the geometries of reptation channels in polymer melts, and non-Gaussianity in the distributions of the end products of gene expression. I have shown here that all these effects are expressions of essentially the same underlying process of stochasticity, which can be described in terms of the dynamics of a point particle or a continuous curve that evolves in simple potentials under the action of white or colored Gaussian noise [8]. I have also shown that this minimal model of time-dependent behavior in condensed phases is amenable to analysis, often exactly, by path integral methods [13-15], which are naturally suited to the treatment of random processes in many-body physics. The results of such analyses are theoretical expressions for various experimentally measured quantities, comparisons with which form the basis for developing physical intuition about the phenomena under study. The general success of this approach to the study of stochasticity in biophysics and molecular biology holds out hopes of its application to other unsolved problems in these fields. These include electrical transport in DNA [143], quantum coherence in photosynthesis [144], power generation in molecular motors [145], cell signaling and chemotaxis [146], space dependent diffusion [147], and self-organization of active matter [148], to name a few. Most of these problems are characterized by non-linearities of one kind or another, so they add a new layer of complexity to the problems considered in this thesis. Although path integral and related field theoretic methods are equipped to handle such complexities, the attendant calculations are expected to be non-trivial, and the challenge to theory will be to devise effective approximation schemes for these methods, or to develop new and more sophisticated methods altogether.

Polymers

Polymers - Fluctuations

Polymers - Conformational Fluctuations

Polymers - Thermodynamic Fluctuations

Polymers - Number Fluctuations

Polymer Dynamics

Polymer Melt Dynamics

Protein Conformational Fluctuations

Elastic Dumbbell Model

Polymeric Systems - Fluctuations

Viscoelasticity

Organic Chemistry

Nanoscale Brownian Dynamics of Semiflexible Biopolymers

Mühle, Steffen

16 July 2020

No description available.

571.4

complex systems

polymer dynamics

brownian motion

elasticity

differential geometry

single-molecule experiment

single-molecule experiments

biophysics

fluorescence correlation spectroscopy

loop formation

translational diffusion

stochastic dynamics

thermal equilibrium

overdamped hydrodynamics

conformational dynamics

protein dynamics

protein folding

loop closure kinetics

intrinsically disordered protein

PET-FCS

2fFCS

hydrodynamic radius

Biologie (PPN619462639)