元粒子:具有可调节和响应特性的计算工程纳米材料

Massimiliano Paesani, Ioana M. Ilie
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摘要

在模拟中,颗粒传统上被视为具有可变尺寸、形状和相互作用参数的刚性平台。虽然这种表示方法适用于刚性核心平台,但由软平台(如胶束、聚合物、弹性体、脂质)组成的粒子在受到外部应力时不可避免地会发生变形。我们为柔性粒子引入了一个通用模型,称之为元粒子(MP)。这些粒子具有可调整的特性,可以对施加的张力做出反应,并且可以变形。元粒子被表示为由类似于弹簧的电势相互连接的伦纳德-琼斯珠的集合。我们对一系列大小和对称性各异的元粒子进行建模,使其受到外部应力的作用,然后在应力释放时发生松弛。各个珠子的位置和方向通过布朗动力学传播。模拟结果表明,元粒子的机械特性随尺寸、珠子排列和受力面积的变化而变化,并且对外加应力具有类似弹性体的响应。此外,元粒子的变形机制各不相同,即小的元粒子只需一步就能改变形状,而大的元粒子则要经过多步变形,珠子内部要重新排列。该模型是开发和了解具有生物医学应用和生物启发元材料设计的可适应特性的微粒的第一步。
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MetaParticles: Computationally engineered nanomaterials with tunable and responsive properties
In simulations, particles are traditionally treated as rigid platforms with variable sizes, shapes and interaction parameters. While this representation is applicable for rigid core platforms, particles consisting of soft platforms (e.g. micelles, polymers, elastomers, lipids) inevitably deform upon application of external stress. We introduce a generic model for flexible particles which we call MetaParticles (MP). These particles have tunable properties, can respond to applied tension and can deform. A metaparticle is represented as a collection of Lennard-Jones beads interconnected by spring-like potentials. We model a series of metaparticles of variable sizes and symmetries, which we subject to external stress followed by relaxation upon stress release. The positions and the orientations of the individual beads are propagated by Brownian dynamics. The simulations show that the mechanical properties of the metaparticles vary with size, bead arrangement and area of applied stress, and share an elastomer-like response to applied stress. Furthermore, metaparticles deform following different mechanisms, i.e., small MPs change shape in one step, while larger ones follow a multi-step deformation pathway, with internal rearrangements of the beads. This model is the first step towards the development and understanding of particles with adaptable properties with biomedical applications and in the design of bioinspired metamaterials.
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