Buckling of stiff polymers: Influence of thermal fluctuations
Copyright policy )Buckling of stiff polymers: Influence of thermal fluctuations
The buckling of biopolymers is a frequently studied phenomenon The influence of thermal fluctuations on the buckling transition is, however, often ignored and not completely understood. A quantitative theory of the buckling of a wormlike chain based on a semiclassical approximation of the partition function is presented. The contribution of thermal fluctuations to the force-extension relation that allows one to go beyond the classical Euler buckling is derived in the linear and nonlinear regimes as well. It is shown that the thermal fluctuations in the nonlinear buckling regime increase the end-to-end distance of the semiflexible rod if it is confined to two dimensions as opposed to the three-dimensional case. The transition to a buckled state softens at finite temperature. We derive the scaling behavior of the transition shift with increasing ratio of contour length versus persistence length.
- Harvard University United States
- Koç University Turkey
- Centre national de la recherche scientifique France
- Leiden University Netherlands
- Institut de Physique France
Models, Molecular, Hot Temperature, Macromolecular Substances, Polymers, Biophysics, Molecular Conformation, Microtubules, Filaments, Supercoiled Dna molecule, Extension, Supercoiled Dna molecule; Entropic elasticity; Persistence length; Stretching Dna; Force; Microtubules; Extension; Filaments; Proteins; Model, Computer Simulation, Force, Models, Statistical, Physics, Proteins, Persistence length, Models, Chemical, Entropic elasticity, Mathematical physics, Physics; Mathematical physics, Stretching Dna, Algorithms, Model
Models, Molecular, Hot Temperature, Macromolecular Substances, Polymers, Biophysics, Molecular Conformation, Microtubules, Filaments, Supercoiled Dna molecule, Extension, Supercoiled Dna molecule; Entropic elasticity; Persistence length; Stretching Dna; Force; Microtubules; Extension; Filaments; Proteins; Model, Computer Simulation, Force, Models, Statistical, Physics, Proteins, Persistence length, Models, Chemical, Entropic elasticity, Mathematical physics, Physics; Mathematical physics, Stretching Dna, Algorithms, Model
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