Lattice stick number 15 is unattainable for non-splittable links

Youngsik Huh; Sungjong No; Seungsang Oh

doi:10.1088/1402-4896/ad6fdf

Lattice stick number 15 is unattainable for non-splittable links

Youngsik Huh
, Sungjong No^*
, Seungsang Oh

^*Corresponding author for this work

Department of Mathematics

Research output: Contribution to journal › Article › peer-review

Abstract

In this paper, we explore mathematical links, defined as closed curves embedded in 3D space. Knot theory studies these structures, which also occur in real-world biopolymers like DNA. Lattice links are links in the cubic lattice. For scientific simulations or statistical studies, links are simplified to lattice links. The lattice stick number, denoted as s _L(K), is the minimum number of lattice sticks needed to represent a link K in the cubic lattice. In previous study, it was shown that only two non-trivial knots and six non-splittable links have s _L ≤ 14: specifically, s L ( 2 1 2 ) = 8 , s L ( 3 1 ) = s L ( 2 1 2 ♯ 2 1 2 ) = s L ( 6 2 3 ) = s L ( 6 3 3 ) = 12 , s L ( 4 1 2 ) = 13 , and s L ( 4 1 ) = s L ( 5 1 2 ) = 14 . Recent study has further revealed that no knot can have s _L = 15. In this paper, we prove that lattice stick number 15 is not attainable for non-splittable links. As a corollary, eleven non-splittable links with s _L=16 are presented.

Original language	English
Article number	105250
Journal	Physica Scripta
Volume	99
Issue number	10
DOIs	https://doi.org/10.1088/1402-4896/ad6fdf
Publication status	Published - 2024 Oct 1

Bibliographical note

Publisher Copyright:
© 2024 IOP Publishing Ltd. All rights, including for text and data mining, AI training, and similar technologies, are reserved.

Keywords

knot
lattice
link

ASJC Scopus subject areas

Atomic and Molecular Physics, and Optics
Mathematical Physics
Condensed Matter Physics

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10.1088/1402-4896/ad6fdf

Cite this

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title = "Lattice stick number 15 is unattainable for non-splittable links",

abstract = "In this paper, we explore mathematical links, defined as closed curves embedded in 3D space. Knot theory studies these structures, which also occur in real-world biopolymers like DNA. Lattice links are links in the cubic lattice. For scientific simulations or statistical studies, links are simplified to lattice links. The lattice stick number, denoted as s L (K), is the minimum number of lattice sticks needed to represent a link K in the cubic lattice. In previous study, it was shown that only two non-trivial knots and six non-splittable links have s L ≤ 14: specifically, s L ( 2 1 2 ) = 8 , s L ( 3 1 ) = s L ( 2 1 2 ♯ 2 1 2 ) = s L ( 6 2 3 ) = s L ( 6 3 3 ) = 12 , s L ( 4 1 2 ) = 13 , and s L ( 4 1 ) = s L ( 5 1 2 ) = 14 . Recent study has further revealed that no knot can have s L = 15. In this paper, we prove that lattice stick number 15 is not attainable for non-splittable links. As a corollary, eleven non-splittable links with s L =16 are presented.",

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author = "Youngsik Huh and Sungjong No and Seungsang Oh",

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AU - Oh, Seungsang

PY - 2024/10/1

Y1 - 2024/10/1

N2 - In this paper, we explore mathematical links, defined as closed curves embedded in 3D space. Knot theory studies these structures, which also occur in real-world biopolymers like DNA. Lattice links are links in the cubic lattice. For scientific simulations or statistical studies, links are simplified to lattice links. The lattice stick number, denoted as s L (K), is the minimum number of lattice sticks needed to represent a link K in the cubic lattice. In previous study, it was shown that only two non-trivial knots and six non-splittable links have s L ≤ 14: specifically, s L ( 2 1 2 ) = 8 , s L ( 3 1 ) = s L ( 2 1 2 ♯ 2 1 2 ) = s L ( 6 2 3 ) = s L ( 6 3 3 ) = 12 , s L ( 4 1 2 ) = 13 , and s L ( 4 1 ) = s L ( 5 1 2 ) = 14 . Recent study has further revealed that no knot can have s L = 15. In this paper, we prove that lattice stick number 15 is not attainable for non-splittable links. As a corollary, eleven non-splittable links with s L =16 are presented.

AB - In this paper, we explore mathematical links, defined as closed curves embedded in 3D space. Knot theory studies these structures, which also occur in real-world biopolymers like DNA. Lattice links are links in the cubic lattice. For scientific simulations or statistical studies, links are simplified to lattice links. The lattice stick number, denoted as s L (K), is the minimum number of lattice sticks needed to represent a link K in the cubic lattice. In previous study, it was shown that only two non-trivial knots and six non-splittable links have s L ≤ 14: specifically, s L ( 2 1 2 ) = 8 , s L ( 3 1 ) = s L ( 2 1 2 ♯ 2 1 2 ) = s L ( 6 2 3 ) = s L ( 6 3 3 ) = 12 , s L ( 4 1 2 ) = 13 , and s L ( 4 1 ) = s L ( 5 1 2 ) = 14 . Recent study has further revealed that no knot can have s L = 15. In this paper, we prove that lattice stick number 15 is not attainable for non-splittable links. As a corollary, eleven non-splittable links with s L =16 are presented.

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ER -

Lattice stick number 15 is unattainable for non-splittable links

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

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