Evolution of Nested Folding States in Compression of a Strongly Confined Semiflexible Chain
ORAL
Abstract
We use Brownian dynamics (BD) simulations to probe the physics of non-equilibrium polymer
compression in extreme nanoconfinement. In our system, modelled on the ‘nanodozer assay’, a gasket
translating at a fixed sliding speed impinges on a nanochannel extended chain. In square channels
with diameter much smaller than the chain persistence length, we find that chain compression
proceeds through a unique folding kinetics driven by repeated double fold nucleation events and
growth of nested folds. We show that the folding kinetics can be understood by coupling a theory
for deterministic contour spooling across the folds with a dynamically varying energy landscape for
fold nucleation. These findings are critical for understanding compression of nanochannel confined
DNA in the sub-persistence length (Odijk) regime.
compression in extreme nanoconfinement. In our system, modelled on the ‘nanodozer assay’, a gasket
translating at a fixed sliding speed impinges on a nanochannel extended chain. In square channels
with diameter much smaller than the chain persistence length, we find that chain compression
proceeds through a unique folding kinetics driven by repeated double fold nucleation events and
growth of nested folds. We show that the folding kinetics can be understood by coupling a theory
for deterministic contour spooling across the folds with a dynamically varying energy landscape for
fold nucleation. These findings are critical for understanding compression of nanochannel confined
DNA in the sub-persistence length (Odijk) regime.
*This work was funded (WR) through the Natural Sciences
and Engineering Research Council of Canada (NSERC)
Discovery Grants Program (Grant No. RGPIN 386212)
and the Fonds de recherche du Quebec Nature et tech-
nologies (FQRNT) Projet d’equipe (PR-180418).
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Presenters
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Aniket Bhattacharya
- Physics, Univ of Central Florida