We present microrheological measurements of the drag force on colloids pulled through a solution of ¿-DNA (used here as a monodisperse model polymer) with an optical tweezer. The experiments show a drag force that is larger than expected from the Stokes formula and the independently measured viscosity of the DNA solution. We attribute this to the accumulation of DNA in front of the colloid and the reduced DNA density behind the colloid. This hypothesis is corroborated by a simple drift-diffusion model for the DNA molecules, which reproduces the experimental data surprisingly well, as well as by corresponding Brownian dynamics simulation
This thesis describes the application of microrheology to characterize the mechanical properties of ...
We present experiments and computer simulations of a “tracer” (or “probe”) particle trapped with opt...
The study of single polymer dynamics has, in the past few years, undergone a resurgence. This has be...
We present microrheological measurements of the drag force on colloids pulled through a solution of ...
DNA molecules were used as a model system to investigate fundamental problems in polymer physics; na...
We explore the depletion attractions that arise between hard colloidal spheres immersed in a non-ads...
Optical tweezers are experimental tools with extraordinary resolution in positioning (± 1 nm) a micr...
This thesis aims to bridge the macroscopic properties and microscopic behavior of macromolecules in ...
We discuss how agreement between single‐molecule imaging methods applied to DNA molecules in flow an...
Single molecule experiments were performed on DNA, a model polymer, and entangled DNA networks to ex...
The goal of our research is to optically visualize shear-induced polymer migration near a surface on...
The simplified artificial environments in which highly complex biological systems are studied do not...
We have developed a Brownian dynamics algorithm for simulating probe and self-diffusion in concentra...
We investigate active particle-tracking microrheology in a colloidal dispersion by Brownian dynamics...
Double-stranded DNA offers a robust platform for investigating fundamental questions regarding the d...
This thesis describes the application of microrheology to characterize the mechanical properties of ...
We present experiments and computer simulations of a “tracer” (or “probe”) particle trapped with opt...
The study of single polymer dynamics has, in the past few years, undergone a resurgence. This has be...
We present microrheological measurements of the drag force on colloids pulled through a solution of ...
DNA molecules were used as a model system to investigate fundamental problems in polymer physics; na...
We explore the depletion attractions that arise between hard colloidal spheres immersed in a non-ads...
Optical tweezers are experimental tools with extraordinary resolution in positioning (± 1 nm) a micr...
This thesis aims to bridge the macroscopic properties and microscopic behavior of macromolecules in ...
We discuss how agreement between single‐molecule imaging methods applied to DNA molecules in flow an...
Single molecule experiments were performed on DNA, a model polymer, and entangled DNA networks to ex...
The goal of our research is to optically visualize shear-induced polymer migration near a surface on...
The simplified artificial environments in which highly complex biological systems are studied do not...
We have developed a Brownian dynamics algorithm for simulating probe and self-diffusion in concentra...
We investigate active particle-tracking microrheology in a colloidal dispersion by Brownian dynamics...
Double-stranded DNA offers a robust platform for investigating fundamental questions regarding the d...
This thesis describes the application of microrheology to characterize the mechanical properties of ...
We present experiments and computer simulations of a “tracer” (or “probe”) particle trapped with opt...
The study of single polymer dynamics has, in the past few years, undergone a resurgence. This has be...