6533b7d4fe1ef96bd12628a4
RESEARCH PRODUCT
Universal monomer dynamics of a two dimensional semi-flexible chain
Aniket BhattacharyaKurt BinderRamesh AdhikariAiqun Huangsubject
Persistence lengthchemistry.chemical_classificationPhysicsQuantitative Biology::BiomoleculesScale (ratio)CrossoverFOS: Physical sciencesGeneral Physics and AstronomyPolymerBendingRadiusCondensed Matter - Soft Condensed MatterCondensed Matter::Soft Condensed MatterchemistryChain (algebraic topology)Biological Physics (physics.bio-ph)ExponentSoft Condensed Matter (cond-mat.soft)Statistical physicsPhysics - Biological Physicsdescription
We present a unified scaling theory for the dynamics of monomers for dilute solutions of semiflexible polymers under good solvent conditions in the free draining limit. Our theory encompasses the well-known regimes of mean square displacements (MSDs) of stiff chains growing like t^{3/4} with time due to bending motions, and the Rouse-like regime t^{2 \nu / (1+ 2\nu)} where \nu is the Flory exponent describing the radius R of a swollen flexible coil. We identify how the prefactors of these laws scale with the persistence length l_p, and show that a crossover from stiff to flexible behavior occurs at a MSD of order l^2_p (at a time proportional to l^3_p). A second crossover (to diffusive motion) occurs when the MSD is of order R^2. Large scale Molecular Dynamics simulations of a bead-spring model with a bond bending potential (allowing to vary l_p from 1 to 200 Lennard-Jones units) provide compelling evidence for the theory, in D=2 dimensions where \nu=3/4. Our results should be valuable for understanding the dynamics of DNA (and other semiflexible biopolymers) adsorbed on substrates.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2013-09-10 |