The effect of a high Reynold's number, pressure-driven flow of a compressible gas on the conformation of an oligomer tethered to the wall of a square channel is studied under both ideal solvent and poor solvent conditions using a hybrid multiparticle collision dynamics and molecular dynamics algorithm. Unlike previous studies, the flow field contains an elongational component in addition to a shear component as well as fluid slip near the walls and results in a Schmidt number for the polymer beads that is less than unity. In both solvent regimes the oligomer is found to extend in the direction of flow. Under the ideal solvent conditions, torsional twisting of the chain and aperiodic cyclical dynamics are observed for the end of the oligomer. Under poor solvent conditions, a metastable helix forms in the end of the chain despite the lack of any attractive potential between beads in the oligomeric chain. The formation of the helix is postulated to be the result of a solvent induced chain collapse that has been confined to a single dimension by a strong flow field.
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7 July 2012
Research Article|
July 03 2012
Simulation of tethered oligomers in nanochannels using multi-particle collision dynamics
Riyad Chetram Raghu;
Riyad Chetram Raghu
a)
Chemical Physics Theory Group, Department of Chemistry,
University of Toronto
, 80 Saint George Street, Ontario M5S 3H6, Canada
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Jeremy Schofield
Jeremy Schofield
b)
Chemical Physics Theory Group, Department of Chemistry,
University of Toronto
, 80 Saint George Street, Ontario M5S 3H6, Canada
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a)
Electronic mail: [email protected].
b)
Electronic mail: [email protected].
J. Chem. Phys. 137, 014901 (2012)
Article history
Received:
February 06 2012
Accepted:
June 13 2012
Citation
Riyad Chetram Raghu, Jeremy Schofield; Simulation of tethered oligomers in nanochannels using multi-particle collision dynamics. J. Chem. Phys. 7 July 2012; 137 (1): 014901. https://doi.org/10.1063/1.4731662
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