Jack Eatson, Susann Bauernfeind, Benjamin Midtvedt, Antonio Ciarlo, Johannes Menath, Giuseppe Pesce, Andrew B. Schofield, Giovanni Volpe, Paul S. Clegg, Nicolas Vogel, D. Martin. A. Buzza, Marcel Rey
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引用次数: 0
Abstract
Ellipsoidal particles confined at liquid interfaces exhibit complex
self-assembly behaviour due to quadrupolar capillary interactions induced by
meniscus deformation. These interactions cause particles to attract each other
in either tip-to-tip or side-to-side configurations. However, controlling their
interfacial self-assembly is challenging because it is difficult to predict
which of these two states will be preferred. In this study, we demonstrate that
introducing a soft shell around hard ellipsoidal particles provides a means to
control the self-assembly process, allowing us to switch the preferred
configuration between these states. We study their interfacial self-assembly
and find that pure ellipsoids without a shell consistently form a "chain-like"
side-to-side assembly, regardless of aspect ratio. In contrast, core-shell
ellipsoids transition from "flower-like" tip-to-tip to "chain-like"
side-to-side arrangements as their aspect ratios increase. The critical aspect
ratio for transitioning between these structures increases with shell-to-core
ratios. Our experimental findings are corroborated by theoretical calculations
and Monte Carlo simulations, which map out the phase diagram of
thermodynamically preferred self-assembly structures for core-shell ellipsoids
as a function of aspect ratio and shell-to-core ratios. This study shows how to
program the self-assembly of anisotropic particles by tuning their
physicochemical properties, allowing the deterministic realization of distinct
structural configurations.