细胞结构中的可调超均匀性

Yiwen Tang, Xinzhi Li, Dapeng Bi
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引用次数: 0

摘要

超均匀材料的特点是当波数趋近于零时,密度波动被抑制,结构因子消失,代表了一种独特的物质状态,跨越了有序性和随机性之间的界限。这些材料具有优异的光学、机械和声学特性,因此在材料科学和工程学领域引起了极大的兴趣。创建超均匀结构的传统方法,包括集合坐标优化和向心Voronoitessellations,主要是计算方法,在捕捉自然发生系统的复杂性方面面临挑战。本研究引入了一个综合理论框架,受上皮组织层中生物细胞集体组织的启发,生成超均匀结构。通过调整细胞弹性和界面张力等参数,我们探索了从流态到僵态的超均匀状态,每种状态都表现出不同的机械特性和密度波动类型。我们的研究结果不仅加深了人们对生物组织超均匀性的理解,还证明了这些材料在为设计具有定制特性的新型材料提供信息方面的潜力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Tunable Hyperuniformity in Cellular Structures
Hyperuniform materials, characterized by their suppressed density fluctuations and vanishing structure factors as the wave number approaches zero, represent a unique state of matter that straddles the boundary between order and randomness. These materials exhibit exceptional optical, mechanical, and acoustic properties, making them of great interest in materials science and engineering. Traditional methods for creating hyperuniform structures, including collective-coordinate optimization and centroidal Voronoi tessellations, have primarily been computational and face challenges in capturing the complexity of naturally occurring systems. This study introduces a comprehensive theoretical framework to generate hyperuniform structures inspired by the collective organization of biological cells within an epithelial tissue layer. By adjusting parameters such as cell elasticity and interfacial tension, we explore a spectrum of hyperuniform states from fluid to rigid, each exhibiting distinct mechanical properties and types of density fluctuations. Our results not only advance the understanding of hyperuniformity in biological tissues but also demonstrate the potential of these materials to inform the design of novel materials with tailored properties.
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