Geometric properties of crumpled wires and the condensed non-solid packing state of very long molecular chains

Gomes, M. A. F.; Brito, V. P.; Araujo, Michelle Silva

doi:10.1590/s0103-50532008000200014

Cited by 22 publications

(22 citation statements)

References 15 publications

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“…If we proceed in our analogy we should expect that the energy E is proportional to the square of the charge, here E ∼ l 2 . This last expression is in agreement with the self-exclusion energy commonly used to model this experiment [17,25,26]. We conjecture that the study of the packing of a wire in a two-dimensional cavity as a capacitor could be useful for the problem of delivery of biopolymers or polymers in biological tissues with the aid of natural or artificial nano carriers [7][8][9][10][11][12].…”

Section: Differential Equation For the (Un)packing Of A Rodsupporting

confidence: 83%

Unpacking of a Crumpled Wire from Two-Dimensional Cavities

et al. 2015

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The physics of tightly packed structures of a wire and other threadlike materials confined in cavities has been explored in recent years in connection with crumpled systems and a number of topics ranging from applications to DNA packing in viral capsids and surgical interventions with catheter to analogies with the electron gas at finite temperature and with theories of two-dimensional quantum gravity. When a long piece of wire is injected into two-dimensional cavities, it bends and originates in the jammed limit a series of closed structures that we call loops. In this work we study the extraction of a crumpled tightly packed wire from a circular cavity aiming to remove loops individually. The size of each removed loop, the maximum value of the force needed to unpack each loop, and the total length of the extracted wire were measured and related to an exponential growth and a mean field model consistent with the literature of crumpled wires. Scaling laws for this process are reported and the relationship between the processes of packing and unpacking of wire is commented upon.

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Section: Differential Equation For the (Un)packing Of A Rodsupporting

confidence: 83%

Unpacking of a Crumpled Wire from Two-Dimensional Cavities

et al. 2015

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“…We study the influence of the available area in rectangular cavities by three different ways: (i) by controlling the total area of the cavity keeping fixed the aspect ratio; (ii) by controlling the width of the cavity keeping fixed its depth; and (iii) by inserting a number of circular discs. The first and second settings can be seen as a study of the finite size effect for this system and can be used to establish a mass-size relationship [16], while the latter corresponds to a model of an elastic one-dimensional object embedded in an environment partially occupied by a competing "fluid".…”

Section: Resultsmentioning

confidence: 99%

“…Although the problem studied here have an intrinsic interest, it could have some additional interest in a number of technological devices and natural processes aiming at accommodating, manipulating, and storing an object with one-dimensional topology in confined environments [14,15,18,19,20,21]. The optimal injection of a long rod of length L into a finite two-dimensional cavity gives origin to a cascade of N loops which are, in general, heterogeneously distributed along the cavity [11,12,16,22,31]. Here, the experimental study of this process is extensively investigated in 27 types of cavities of several sizes and topologies.…”

Section: Discussionmentioning

confidence: 99%

“…In these circumstances, the morphologies of the structures formed have a larger surface area as compared to the bulk content, and they can be easily accessed for image recording. Beyond the intrinsic theoretical interests, the problem discussed here has connections with some important issues in the life sciences, as the packing of DNA molecules in viral capsids [14,15,16,17], the physics of an unbranched polymer in confined geometries [18,19], and the problem of packing and delivery of a polymer-like drug with the aid of nano-capsids [20,21]. The packing process studied here generates a planar pattern with a set of loops that is somewhat similar to the classical two-dimensional packing of discs, a problem that has a wide range of applications in technology and science, including the structures of glasses, crystals, granular piles, molecular films and foams [22].…”

Section: Introductionmentioning

confidence: 99%

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Tight packing of a flexible rod in two-dimensional cavities

Sobral¹,

Gomes²

2015

J. Phys. D: Appl. Phys.

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Abstract. The present work deals with the injection and packing of a flexible polymeric rod of length L into a simply connected rectangular domain of area XY . As the injection proceeds, the rod bends over itself and it stores elastic energy in closed loops. In a typical experiment N of these loops can be identified inside the cavity in the jammed state. We have performed an extensive experimental analysis of the total length L(N, X, Y ) in the tight packing limit, and have obtained robust power laws relating these variables. Additionally, we have examined a version of this packing problem when the simply connected domain is partially occupied with free discs of fixed size. The experimental results were obtained with 27 types of cavities and obey a single equation of state valid for the tight packing of rods in domains of different topologies. Besides its intrinsic theoretical interest and generality, the problem examined here could be of interest in a number of studies including package models of DNA and polymers in several complex environments.

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“…The desktop experiment described here is only meant to illustrate the part of the DNA-phage system behavior relating to the capstan mechanism and is not macroscopic mechanical models to represent the phage-DNA system [28,29,30].…”

Section: Discussionmentioning

confidence: 99%

A mechanical model of bacteriophage DNA ejection

Arun¹,

Ghosal

2017

Physics Letters A

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Single molecule experiments on bacteriophages show an exponential scaling for the dependence of mobility on the length of DNA within the capsid. It has been suggested that this could be due to the "capstan mechanism" -- the exponential amplification of friction forces that result when a rope is wound around a cylinder as in a ship's capstan. Here we describe a desktop experiment that illustrates the effect. Though our model phage is a million times larger, it exhibits the same scaling observed in single molecule experiments.Comment: 17 pages, 2 figures, 1 table + Supplementary Informatio

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Geometric properties of crumpled wires and the condensed non-solid packing state of very long molecular chains

Cited by 22 publications

References 15 publications

Unpacking of a Crumpled Wire from Two-Dimensional Cavities

Unpacking of a Crumpled Wire from Two-Dimensional Cavities

Tight packing of a flexible rod in two-dimensional cavities

A mechanical model of bacteriophage DNA ejection

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