Bounds for the minimum step number of knots confined to slabs in the simple cubic lattice

Ishihara, Kai; Scharein, Robert G.; Diao, Yuanan; Arsuaga, Javier; Vázquez, Mariel; Shimokawa, Kuniyasu

doi:10.1088/1751-8113/45/6/065003

Cited by 10 publications

(29 citation statements)

References 39 publications

(73 reference statements)

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“…An implementation of the GAS-algorithm for knotted cubic lattice polygons in slabs [11] was used, and we collected data on the entropy and minimal length of knotted lattice polygons up to eight crossings. Our data verify similar results obtained in reference [8]. In section 3 we discuss the first model and present our data, and in section 4 we present data on the second model and discuss our results.…”

Section: Introductionsupporting

confidence: 85%

“…Since the GAS algorithm can be implemented as a flat histogram method, it is efficient at rare event sampling and thus at finding knotted polygons of minimal length. A comparison of our results with the data in reference [8] makes us confident that our results are exact in almost all cases.…”

Section: Numerical Approachsupporting

confidence: 79%

“…The data in table 5 agree for all knot types, except for 8 18 , with the data in reference [8]. We improved on the estimate for the minimal length of 8 18 in S 1 by finding states at length n = 70, compared to 72 in that reference.…”

Section: Numerical Approachmentioning

confidence: 52%

“…In both these models it is necessary to determine the number and length of lattice knots in slabs of width L. Some data of this kind were obtained in reference [8], and we will at the same time verify in most cases, and improve in one case, on their results.…”

Section: Numerical Approachmentioning

confidence: 91%

“…For example, one may deduce that n 2,31 = 24 from reference [4]. However, simulations show that n 1,31 = 26 [8]. In other words, in a slab of width L = 1, it is necessary to have a polygon of length 26 to tie a lattice trefoil, while if L ≥ 2 then 24 edges will be sufficient (and necessary) [4].…”

Section: Models Of Lattice Knots In Slabsmentioning

confidence: 99%

See 4 more Smart Citations

Lattice knots in a slab

Gasumova¹,

Rensburg²,

Rechnitzer³

2012

J. Stat. Mech.

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Abstract. In this paper the number and lengths of minimal length lattice knots confined to slabs of width L, is determined. Our data on minimal length verify the results by Ishihara et. al. [8] for the similar problem, expect in a single case, where an improvement is found. From our data we construct two models of grafted knotted ring polymers squeezed between hard walls, or by an external force. In each model, we determine the entropic forces arising when the lattice polygon is squeezed by externally applied forces. The profile of forces and compressibility of several knot types are presented and compared, and in addition, the total work done on the lattice knots when it is squeezed to a minimal state is determined.

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Section: Introductionsupporting

confidence: 85%

Section: Numerical Approachsupporting

confidence: 79%

Section: Numerical Approachmentioning

confidence: 52%

Section: Numerical Approachmentioning

confidence: 91%

Section: Models Of Lattice Knots In Slabsmentioning

confidence: 99%

See 3 more Smart Citations

Lattice knots in a slab

Gasumova¹,

Rensburg²,

Rechnitzer³

2012

J. Stat. Mech.

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An Introduction to KnotPlot

Scharein,

Rawdon

2024

Lecture Notes in Mathematics

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Pathways of DNA unlinking: A story of stepwise simplification

Stolz

Yoshida

Brasher

et al. 2017

Sci Rep

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In Escherichia coli DNA replication yields interlinked chromosomes. Controlling topological changes associated with replication and returning the newly replicated chromosomes to an unlinked monomeric state is essential to cell survival. In the absence of the topoisomerase topoIV, the site-specific recombination complex XerCD- dif-FtsK can remove replication links by local reconnection. We previously showed mathematically that there is a unique minimal pathway of unlinking replication links by reconnection while stepwise reducing the topological complexity. However, the possibility that reconnection preserves or increases topological complexity is biologically plausible. In this case, are there other unlinking pathways? Which is the most probable? We consider these questions in an analytical and numerical study of minimal unlinking pathways. We use a Markov Chain Monte Carlo algorithm with Multiple Markov Chain sampling to model local reconnection on 491 different substrate topologies, 166 knots and 325 links, and distinguish between pathways connecting a total of 881 different topologies. We conclude that the minimal pathway of unlinking replication links that was found under more stringent assumptions is the most probable. We also present exact results on unlinking a 6-crossing replication link. These results point to a general process of topology simplification by local reconnection, with applications going beyond DNA.

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Bounds for the minimum step number of knots confined to slabs in the simple cubic lattice

Cited by 10 publications

References 39 publications

Lattice knots in a slab

Lattice knots in a slab

An Introduction to KnotPlot

Pathways of DNA unlinking: A story of stepwise simplification

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