Add to ORKGWe present a model for semiflexible polymers in Hamiltonian formulation which interpolates between a Rouse chain and worm-like chain. Both models are realized as limits for the parameters. The model parameters can also be chosen to match the experimental force-extension curve for double-stranded DNA. Near the ground state of the Hamiltonian, the eigenvalues for the longitudinal (stretching) and the transversal (bending) modes of a chain with N springs, indexed by p, scale as lambda_lp ~ (p/N)^2 and lambda_tp ~ p^2(p-1)^2/N^4 respectively for small p. We also show that the associated decay times tau_p ~ (N/p)^4 will not be observed if they exceed the orientational time scale tau_r ~ N^3 for an equally-long rigid rod, as the driven decay is t...
A new formula for the force vs. extension relation is derived from the discrete version of the so-ca...
We present a unified scaling theory for the dynamics of monomers for dilute solutions of semi-flexib...
A new formula for the force vs. extension relation is derived from the discrete version of the so-ca...
Open Access. Also selected for Virtual Journal of Biological Physics Research - December 1, 2002We p...
NA bending on length scales shorter than a persistence length plays an integral role in the translat...
Based on the wormlike chain model, a coarse-grained description of the nonlinear dynamics of a weakl...
AbstractWe present theory and simulations to describe nonequilibrium stretching of semiflexible chai...
We present a unified scaling theory for the dynamics of monomers for dilute solutions of semi-flexib...
We compute the effect of hydrodynamic interaction and stretching on the fluctuation properties of a ...
We present a unified scaling theory for the dynamics of monomers for dilute solutions of semi-flexib...
We investigate the simulation of stiff (extensible) and rigid (inextensible) semiflexible polymers i...
We investigate the simulation of stiff (extensible) and rigid (inextensible) semiflexible polymers i...
By large-scale Monte Carlo simulations of semiflexible polymers in d=2 dimensions the applicability ...
ABSTRACT We present theory and simulations to describe nonequilibrium stretching of semiflexible cha...
A new formula for the force vs. extension relation is derived from the discrete version of the so-ca...
A new formula for the force vs. extension relation is derived from the discrete version of the so-ca...
We present a unified scaling theory for the dynamics of monomers for dilute solutions of semi-flexib...
A new formula for the force vs. extension relation is derived from the discrete version of the so-ca...
Open Access. Also selected for Virtual Journal of Biological Physics Research - December 1, 2002We p...
NA bending on length scales shorter than a persistence length plays an integral role in the translat...
Based on the wormlike chain model, a coarse-grained description of the nonlinear dynamics of a weakl...
AbstractWe present theory and simulations to describe nonequilibrium stretching of semiflexible chai...
We present a unified scaling theory for the dynamics of monomers for dilute solutions of semi-flexib...
We compute the effect of hydrodynamic interaction and stretching on the fluctuation properties of a ...
We present a unified scaling theory for the dynamics of monomers for dilute solutions of semi-flexib...
We investigate the simulation of stiff (extensible) and rigid (inextensible) semiflexible polymers i...
We investigate the simulation of stiff (extensible) and rigid (inextensible) semiflexible polymers i...
By large-scale Monte Carlo simulations of semiflexible polymers in d=2 dimensions the applicability ...
ABSTRACT We present theory and simulations to describe nonequilibrium stretching of semiflexible cha...
A new formula for the force vs. extension relation is derived from the discrete version of the so-ca...
A new formula for the force vs. extension relation is derived from the discrete version of the so-ca...
We present a unified scaling theory for the dynamics of monomers for dilute solutions of semi-flexib...
A new formula for the force vs. extension relation is derived from the discrete version of the so-ca...