Abstract
Recently, it has been demonstrated [Magee , Phys. Rev. Lett. 96, 207802
(2006)] that isolated square-well homopolymers can spontaneously break
chiral symmetry and "freeze" into helical structures at sufficiently
low temperatures. This behavior is interesting because the square-well
homopolymer is itself achiral. In this work, we use event-driven
molecular dynamics combined with an optimized parallel tempering scheme
to study this polymer model over a wide range of parameters. We examine
the conditions where the helix structure is stable and determine how
the interaction parameters of the polymer govern the details of the
helix structure. The width of the square well (proportional to lambda)
is found to control the radius of the helix, which decreases with
increasing well width until the polymer forms a coiled sphere for
sufficiently large wells. The helices are found to be stable for only a
"window" of molecular weights. If the polymer is too short, the helix
will not form. If the polymer is too long, the helix is no longer the
minimum energy structure, and other folded structures will form. The
size of this window is governed by the chain stiffness, which in this
model is a function of the ratio of the monomer size to the bond
length. Outside this window, the polymer still freezes into a locked
structure at low temperature; however, unless the chain is sufficiently
stiff, this structure will not be unique and is similar to a glassy
state.
Original language | English |
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Number of pages | 8 |
Journal | Physical Review E |
Volume | 80 |
Issue number | 2 |
DOIs | |
Publication status | Published - 26 Aug 2009 |
Keywords
- chiral symmetries
- molecular dynamics method
- polymers