English

Stretching Homopolymers

Soft Condensed Matter 2009-11-13 v1

Abstract

Force induced stretching of polymers is important in a variety of contexts. We have used theory and simulations to describe the response of homopolymers, with NN monomers, to force (ff) in good and poor solvents. In good solvents and for {{sufficiently large}} NN we show, in accord with scaling predictions, that the mean extension along the ff axis <Z>f<Z>\sim f for small ff, and <Z>f2/3<Z>\sim f^{{2/3}} (the Pincus regime) for intermediate values of ff. The theoretical predictions for \laZ\ra\la Z\ra as a function of ff are in excellent agreement with simulations for N=100 and 1600. However, even with N=1600, the expected Pincus regime is not observed due to the the breakdown of the assumptions in the blob picture for finite NN. {{We predict the Pincus scaling in a good solvent will be observed for N105N\gtrsim 10^5}}. The force-dependent structure factors for a polymer in a poor solvent show that there are a hierarchy of structures, depending on the nature of the solvent. For a weakly hydrophobic polymer, various structures (ideal conformations, self-avoiding chains, globules, and rods) emerge on distinct length scales as ff is varied. A strongly hydrophobic polymer remains globular as long as ff is less than a critical value fcf_c. Above fcf_c, an abrupt first order transition to a rod-like structure occurs. Our predictions can be tested using single molecule experiments.

Keywords

Cite

@article{arxiv.0705.3029,
  title  = {Stretching Homopolymers},
  author = {Greg Morrison and Changbong Hyeon and N. M. Toan and Bae-Yeun Ha and D. Thirumalai},
  journal= {arXiv preprint arXiv:0705.3029},
  year   = {2009}
}
R2 v1 2026-06-21T08:30:19.293Z