We investigate,by a Brownian Dynamics (BD) simulation,the collapse of a single, semiflexible or stiff polymer in solution,in the presence of short-range,attractive interactions. In contrast to the mechanism for flexible chains,our results suggest that the collapse occurs via a series of long-lived,metastable intermediates. These intermediates form a well-defined, hierarchical family of conformations. Experiments with DNA condensation have shown similar shapes,which were described as "tennis racquets". In addition to our primary observation concerning the collapse pathways of stiff filaments,we note that,in the absence of fluctuations (upon annealing),the shape of these intermediates can be calculated exactly in certain limits, and is given by a particular case of Euler's elastica. This shape is unique up to an overall scale factor determined by the parameters for bending stiffness and short-range attraction.
[1]
G. M.,et al.
A Treatise on the Mathematical Theory of Elasticity
,
1906,
Nature.
[2]
H. Stanley,et al.
Statistical physics of macromolecules
,
1995
.
[3]
David J. Goodman,et al.
Personal Communications
,
1994,
Mobile Communications.
[4]
G. Fredrickson.
The theory of polymer dynamics
,
1996
.
[5]
P. Gennes.
Scaling Concepts in Polymer Physics
,
1979
.