Alexander V. Petrunin, Tom Höfken, Stefanie Schneider, Pablo Mota-Santiago, Judith E. Houston and Andrea Scotti
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引用次数: 0
Abstract
Soft colloids are widely used to study glass transition, aging and jamming. A high size polydispersity is typically introduced in these systems to avoid crystal formation. Here, we use binary mixtures of hollow and regular microgels with comparable sizes to inhibit crystallization. The phase behavior of the mixture is probed as a function of the number fraction of hollow microgels and characterized by small-angle X-ray scattering. Molecular dynamic simulations are used to extract the particle–particle pair potential and obtain insight on their deformation. The results suggest that the high deformability of the hollow microgels offers an alternative route to maximize the entropy without crystal formation.
软胶体被广泛用于研究玻璃转化、老化和干扰。在这些系统中通常会引入高尺寸多分散性,以避免晶体形成。在这里,我们使用具有可比尺寸的空心微凝胶和规则微凝胶的二元混合物来抑制结晶。混合物的相行为是空心微凝胶数量分数的函数,并通过小角 X 射线散射进行表征。分子动力学模拟用于提取粒子-粒子对势能,并深入了解它们的变形情况。研究结果表明,空心微凝胶的高变形性为在不形成晶体的情况下实现熵的最大化提供了另一条途径。
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