Conformation and translational diffusion of a xanthan polyelectrolyte chain: Brownian dynamics simulation and single molecule tracking

Authors
Chun, Myung-SukKim, ChongyoupLee, Duck E.
Issue Date
2009-05
Publisher
AMER PHYSICAL SOC
Citation
PHYSICAL REVIEW E, v.79, no.5
Abstract
In our recent Brownian dynamics (BD) simulation study, the structure and dynamics of anionic polyelectrolyte xanthan in bulk solution as well as confined spaces of slitlike channel were examined by applying a coarse-grained model with nonlinear bead-spring discretization of a whole chain [J. Jeon and M.-S. Chun, J. Chem. Phys. 126, 154904 (2007)]. This model goes beyond other simulations as they did not consider both long-range electrostatic and hydrodynamic interactions between pairs of beads. Simulation parameters are obtained from the viscometric method of rheology data on the native and sonicated xanthan polysaccharides, which have a contour length less than 1 mu m. The size of the semiflexible polyelectrolyte can be well described by the wormlike chain model once the electrostatic effects are taken into account by the persistence length measured at a long length scale. For experimental verifications, single molecule visualization was performed on fluorescein-labeled xanthan using an inverted fluorescence microscope, and the motion of an individual molecule was quantified. Experimental results on the conformational changes in xanthan chain in the electrolyte solution have a reasonable trend to agree with the prediction by BD simulations. In the translational diffusion induced by the Debye screening effect, the simulation prediction reveals slightly higher values compared to those of our measurements, although it agrees with the literature data. Considering the experimental restrictions, our BD simulations are verified to model the single polyelectrolyte well.
Keywords
DNA-MOLECULES; SHAPE; POLYMER; TRANSPORT; RHEOLOGY; MODEL; DNA-MOLECULES; SHAPE; POLYMER; TRANSPORT; RHEOLOGY; MODEL; Brownian motion; diffusion; fluorescence; hydrodynamics; liquid structure; liquid theory; polymer electrolytes; polymer solutions; rheology
ISSN
1539-3755
URI
https://pubs.kist.re.kr/handle/201004/132511
DOI
10.1103/PhysRevE.79.051919
Appears in Collections:
KIST Article > 2009
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