Shear-induced structural and viscosity changes of amphiphilic patchy nanocubes in suspension

IF 3.2 3区 工程技术 Q2 CHEMISTRY, PHYSICAL
Takahiro Ikeda, Yusei Kobayashi and Masashi Yamakawa
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Abstract

Structure formation and rheological properties of amphiphilic patchy nanocubes in equilibrium and under shear were investigated using hybrid molecular dynamics simulations combined with multiparticle collision dynamics that consider hydrodynamic interactions. The relationship between complex self-assembled structures and the resulting macroscopic properties has not yet been examined because of the computational complexity these multiscale problems present. The number and location of solvophobic patches on the amphiphilic nanocubes were varied at several colloid volume fractions in the liquid regime. For a pure suspension of one-patch cubes, the nanocubes self-assemble into dimers in the equilibrium state because bonded one-patch cubes have no exposed solvophobic surfaces. At low shear rates, small dimers undergo shear-induced alignment along the flow direction. This results in shear-thinning accompanied by slightly higher shear viscosity (≈15%) than homoparticle dispersions of the same concentration. As the shear rate increases further, the suspensions exhibit Newtonian-like behavior until the cluster disintegrates, followed by shear thinning with breakdown into individual cubes. For binary mixtures of one- and two-patch nanocubes, the resulting cluster shapes, which include elongated rods and fractal objects, can be controlled by the patch arrangements on the two-patch cubes. Interestingly, despite the differences in the shape and resistance of the clusters, two different mixtures undergo a similar increase in the shear viscosity (≈35%) compared to the homoparticle dispersions, to essentially exhibit rheological behavior similar that of a pure suspension of one-patch cubes. Our findings provide new insights into the correlation between microscopic (design of patchy cubes), mesoscopic (self-assembled structures), and macroscopic (viscosity) properties, and are also valuable for identifying the synthesis conditions required to realize novel materials with the desired properties and functionalities.

Abstract Image

悬浮液中两亲斑状纳米立方体的剪切诱导结构和粘度变化
利用混合分子动力学模拟结合考虑了流体动力学相互作用的多粒子碰撞动力学,研究了两亲性斑块纳米立方体在平衡和剪切条件下的结构形成和流变特性。由于这些多尺度问题的计算复杂性,复杂的自组装结构与由此产生的宏观特性之间的关系尚未得到研究。两亲性纳米立方体上的疏溶斑块的数量和位置在液体状态下的几种胶体体积分数下变化。对于单补丁立方体的纯悬浮液,由于粘结的单补丁立方体没有暴露的疏溶表面,因此纳米立方体在平衡状态下会自组装成二聚体。在低剪切速率下,小的二聚体沿流动方向发生剪切对齐。这导致剪切稀化,同时剪切粘度(≈ 15%)略高于相同浓度的均粒分散体。随着剪切速率的进一步增加,悬浮液表现出类似牛顿的行为,直到团块解体,随后剪切变稀,分解成单个立方体。对于单补丁和双补丁纳米立方体的二元混合物,双补丁立方体上的补丁排列可以控制所产生的团簇形状,包括拉长的棒状和分形物体。有趣的是,尽管团簇的形状和阻力不同,但与同颗粒分散体相比,两种不同混合物的剪切粘度有相似的增加(≈ 35%),基本上表现出与纯单补丁立方体悬浮液相似的流变行为。我们的发现为微观(斑块立方体的设计)、中观(自组装结构)和宏观(粘度)特性之间的相关性提供了新的见解,对于确定实现具有所需特性和功能的新型材料所需的合成条件也很有价值。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Molecular Systems Design & Engineering
Molecular Systems Design & Engineering Engineering-Biomedical Engineering
CiteScore
6.40
自引率
2.80%
发文量
144
期刊介绍: Molecular Systems Design & Engineering provides a hub for cutting-edge research into how understanding of molecular properties, behaviour and interactions can be used to design and assemble better materials, systems, and processes to achieve specific functions. These may have applications of technological significance and help address global challenges.
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