各向异性管的螺旋紧密堆积

IF 2.8 2区 物理与天体物理 Q2 PHYSICS, MULTIDISCIPLINARY
Benjamin R Greenvall, Gregory M Grason
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引用次数: 0

摘要

从纳米生物分子到宏观结构组件,螺旋紧密堆积状态的细丝在天然和工程材料系统中都很常见。理想绳索模型所描述的最简单的螺旋紧密堆积模型忽略了垂直于主干的各向异性,而物理细丝的横截面往往与圆形相去甚远。在这里,我们考虑了理想绳索模型的各向异性广义化,并证明横截面各向异性对螺旋丝的螺旋紧密堆积构型具有强烈的非线性影响。我们表明,紧密堆积景观的拓扑结构和组成取决于横截面长宽比,并以几种不同的自接触状态为特征。我们根据 "虚拟 "圆柱毛细管内的限制概念,描述了这些不同状态的局部密度,并表明最佳密度状态随各向异性程度的变化而强烈不同。虽然各向同性丝在直线配置中密度最大,但任何程度的各向异性都会导致最大密度状态的螺旋性。我们的研究表明,随着各向异性的增加,最大密度态在螺旋几何形状和横截面倾斜度上呈现出一连串的转变,从螺旋带状到螺旋螺旋包装。此外,我们还表明,在大各向异性的螺旋螺旋极限中,最大毛细管密度在体积分数为 π/4 的下限时达到饱和。众所周知,横截面各向异性会影响细丝的机械性能,而我们的研究则表明,各向异性对塑造这种基本材料图案的构型空间和堆积效率有很大影响。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Helical close-packing of anisotropic tubes
Helically close-packed states of filaments are common in natural and engineered material systems, ranging from nanoscopic biomolecules to macroscopic structural components. While the simplest models of helical close-packing, described by the ideal rope model, neglect anisotropy perpendicular to the backbone, physical filaments are often quite far from circular in their cross-section. Here, we consider an anisotropic generalization of the ideal rope model and show that cross-section anisotropy has a strongly non-linear impact on the helical close-packing configurations of helical filaments. We show that the topology and composition of the close-packing landscape depends on the cross-sectional aspect ratio and is characterized by several distinct states of self-contact. We characterize the local density of these distinct states based on the notion of confinement within a ‘virtual’ cylindrical capillary, and show that states of optimal density vary strongly with the degree of anisotropy. While isotropic filaments are densest in a straight configuration, any measure of anisotropy leads to helicity of the maximal density state. We show the maximally dense states exhibit a sequence of transitions in helical geometry and cross-sectional tilt with increasing anisotropy, from spiral tape to spiral screw packings. Furthermore, we show that maximal capillary density saturates in a lower bound for volume fraction of π/4 in the large-anisotropy, spiral-screw limit. While cross-sectional anisotropy is well-known to impact the mechanical properties of filaments, our study shows its strong effects to shape the configuration space and packing efficiency of this elementary material motif.
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来源期刊
New Journal of Physics
New Journal of Physics 物理-物理:综合
CiteScore
6.20
自引率
3.00%
发文量
504
审稿时长
3.1 months
期刊介绍: New Journal of Physics publishes across the whole of physics, encompassing pure, applied, theoretical and experimental research, as well as interdisciplinary topics where physics forms the central theme. All content is permanently free to read and the journal is funded by an article publication charge.
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