366 research outputs found
Phase diagram of force-induced DNA unzipping in exactly solvable models
The mechanical separation of the double helical DNA structure induced by
forces pulling apart the two DNA strands (``unzipping'') has been the subject
of recent experiments. Analytical results are obtained within various models of
interacting pairs of directed walks in the (1,1,...,1) direction on the
hypercubic lattice, and the phase diagram in the force-temperature plane is
studied for a variety of cases. The scaling behaviour is determined at both the
unzipping and the melting transition. We confirm the existence of a cold
denaturation transition recently observed in numerical simulations: for a
finite range of forces the system gets unzipped by {\it decreasing} the
temperature. The existence of this transition is rigorously established for
generic lattice and continuum space models.Comment: 19 pages, 5 eps figures; revised version with minor changes,
presentation simplified in the text with details in appendix. Accepted for
publication in Phys. Rev.
Facilitated diffusion on confined DNA
In living cells, proteins combine 3D bulk diffusion and 1D sliding along the
DNA to reach a target faster. This process is known as facilitated diffusion,
and we investigate its dynamics in the physiologically relevant case of
confined DNA. The confining geometry and DNA elasticity are key parameters: we
find that facilitated diffusion is most efficient inside an isotropic volume,
and on a flexible polymer. By considering the typical copy numbers of proteins
in vivo, we show that the speedup due to sliding becomes insensitive to fine
tuning of parameters, rendering facilitated diffusion a robust mechanism to
speed up intracellular diffusion-limited reactions. The parameter range we
focus on is relevant for in vitro systems and for facilitated diffusion on
yeast chromatin
Polymer packaging and ejection in viral capsids: shape matters
We use a mesoscale simulation approach to explore the impact of different
capsid geometries on the packaging and ejection dynamics of polymers of
different flexibility. We find that both packing and ejection times are faster
for flexible polymers. For such polymers a sphere packs more quickly and ejects
more slowly than an ellipsoid. For semiflexible polymers, however, the case
relevant to DNA, a sphere both packs and ejects more easily. We interpret our
results by considering both the thermodynamics and the relaxational dynamics of
the polymers. The predictions could be tested with bio-mimetic experiments with
synthetic polymers inside artificial vesicles. Our results suggest that phages
may have evolved to be roughly spherical in shape to optimise the speed of
genome ejection, which is the first stage in infection.Comment: 4 pages, 4 figure
Phase diagram for unzipping DNA with long-range interactions
We present a critique and extension of the mean-field approach to the
mechanical pulling transition in bound polymer systems. Our model is motivated
by the theoretically and experimentally important examples of adsorbed polymers
and double-stranded DNA, and we focus on the case in which quenched disorder in
the sequence of monomers is unimportant for the statistical mechanics. We show
how including excluded volume interactions in the model affects the phase
diagram for the critical pulling force, and we predict a re-entrancy phase at
low temperatures which has not been previously discussed. We also consider the
case of non-equilibrium pulling, in which the external force probes the local,
rather than the global structure of the dsDNA or adsorbed polymer. The dynamics
of the pulling transition in such experiments could illuminate the polymer's
loop structure, which depends on the nature of excluded volume interactions.Comment: 4 pages, 2 figures; this version clarifies Eq. 8, and corrects errors
in Fig.
Switching dynamics in cholesteric blue phases
Blue phases are networks of disclination lines, which occur in cholesteric
liquid crystals near the transition to the isotropic phase. They have recently
been used for the new generation of fast switching liquid crystal displays.
Here we study numerically the steady states and switching hydrodynamics of blue
phase I (BPI) and blue phase II (BPII) cells subjected to an electric field.
When the field is on, there are three regimes: for very weak fields (and strong
anchoring at the boundaries) the blue phases are almost unaffected, for
intermediate fields the disclinations twist (for BPI) and unzip (for BPII),
whereas for very large voltages the network dissolves in the bulk of the cell.
Interestingly, we find that a BPII cell can recover its original structure when
the field is switched off, whereas a BPI cell is found to be trapped more
easily into metastable configurations. The kinetic pathways followed during
switching on and off entails dramatic reorganisation of the disclination
networks. We also discuss the effect of changing the director field anchoring
at the boundary planes and of varying the direction of the applied field.Comment: 17 pages, 11 figure
Lattice Boltzmann Algorithm for three-dimensional liquid crystal hydrodynamics
We describe a lattice Boltzmann algorithm to simulate liquid crystal
hydrodynamics in three dimensions. The equations of motion are written in terms
of a tensor order parameter. This allows both the isotropic and the nematic
phases to be considered. Backflow effects and the hydrodynamics of topological
defects are naturally included in the simulations, as are viscoelastic effects
such as shear-thinning and shear-banding. We describe the implementation of
velocity boundary conditions and show that the algorithm can be used to
describe optical bounce in twisted nematic devices and secondary flow in
sheared nematics with an imposed twist.Comment: 12 pages, 3 figure
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