Exact solution for the force-extension relation of a semiflexible polymer under compression

Exact solutions for the elastic and thermodynamic properties for the wormlike chain model are elaborated in terms of Mathieu functions. The smearing of the classical Euler buckling instability for clamped polymers is analyzed for the force-extension relation. Interestingly, at strong compression for...

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Bibliographic Details
Published in:Physical review. E 2017-05, Vol.95 (5-1), p.052501-052501, Article 052501
Main Authors: Kurzthaler, Christina, Franosch, Thomas
Format: Article
Language:English
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Summary:Exact solutions for the elastic and thermodynamic properties for the wormlike chain model are elaborated in terms of Mathieu functions. The smearing of the classical Euler buckling instability for clamped polymers is analyzed for the force-extension relation. Interestingly, at strong compression forces the thermal fluctuations lead to larger elongations than for the elastic rod. The susceptibility defined as the derivative of the force-extension relation displays a prominent maximum at a force that approaches the critical Euler buckling force as the persistence length is increased. We also evaluate the excess entropy and heat capacity induced by the compression and find that they vary nonmonotonically with the load. These findings are corroborated by pseudo-Brownian simulations.
ISSN:2470-0045
2470-0053
DOI:10.1103/PhysRevE.95.052501