Elastic lattice polymers

M. Baiesi; G.T. Barkema; E. Carlon

doi:10.1103/PhysRevE.81.061801

Elastic lattice polymers

M. Baiesi, G.T. Barkema, E. Carlon

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Abstract

We study a model of “elastic” lattice polymer in which a fixed number of monomers m is hosted by a self-avoiding walk with fluctuating length l. We show that the stored length density m 1− l /m scales asymptotically for large m as m= 1− /m+. . . , where is the polymer entropic exponent, so that can be determined from the analysis of m. We perform simulations for elastic lattice polymer loops with various sizes and knots, in which we measure m. The resulting estimates support the hypothesis that the exponent is determined only by the number of prime knots and not by their type. However, if knots are present, we observe strong corrections to scaling, which help to understand how an entropic competition between knots is affected by the finite length of the chain.

Original language	English
Pages (from-to)	061801/1-061801/9
Number of pages	9
Journal	Physical Review. E, Statistical, nonlinear, and soft matter physics
Volume	81
Issue number	6
DOIs	https://doi.org/10.1103/PhysRevE.81.061801
Publication status	Published - 2010

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Cited By (since 1996): 1

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abstract = "We study a model of “elastic” lattice polymer in which a fixed number of monomers m is hosted by a self-avoiding walk with fluctuating length l. We show that the stored length density m 1− l /m scales asymptotically for large m as m= 1− /m+. . . , where is the polymer entropic exponent, so that can be determined from the analysis of m. We perform simulations for elastic lattice polymer loops with various sizes and knots, in which we measure m. The resulting estimates support the hypothesis that the exponent is determined only by the number of prime knots and not by their type. However, if knots are present, we observe strong corrections to scaling, which help to understand how an entropic competition between knots is affected by the finite length of the chain.",

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AU - Barkema, G.T.

AU - Carlon, E.

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N2 - We study a model of “elastic” lattice polymer in which a fixed number of monomers m is hosted by a self-avoiding walk with fluctuating length l. We show that the stored length density m 1− l /m scales asymptotically for large m as m= 1− /m+. . . , where is the polymer entropic exponent, so that can be determined from the analysis of m. We perform simulations for elastic lattice polymer loops with various sizes and knots, in which we measure m. The resulting estimates support the hypothesis that the exponent is determined only by the number of prime knots and not by their type. However, if knots are present, we observe strong corrections to scaling, which help to understand how an entropic competition between knots is affected by the finite length of the chain.

AB - We study a model of “elastic” lattice polymer in which a fixed number of monomers m is hosted by a self-avoiding walk with fluctuating length l. We show that the stored length density m 1− l /m scales asymptotically for large m as m= 1− /m+. . . , where is the polymer entropic exponent, so that can be determined from the analysis of m. We perform simulations for elastic lattice polymer loops with various sizes and knots, in which we measure m. The resulting estimates support the hypothesis that the exponent is determined only by the number of prime knots and not by their type. However, if knots are present, we observe strong corrections to scaling, which help to understand how an entropic competition between knots is affected by the finite length of the chain.

U2 - 10.1103/PhysRevE.81.061801

DO - 10.1103/PhysRevE.81.061801

M3 - Article

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SP - 061801/1-061801/9

JO - Physical Review. E, Statistical, nonlinear, and soft matter physics

JF - Physical Review. E, Statistical, nonlinear, and soft matter physics

IS - 6

ER -

Elastic lattice polymers

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