Viologen-based supramolecular crystal gels: gelation kinetics and sensitivity to temperature

IF 2.9 3区 化学 Q3 CHEMISTRY, PHYSICAL Soft Matter Pub Date : 2024-10-01 DOI:10.1039/D4SM00826J
Julien Bauland, Vivien Andrieux, Frédéric Pignon, Denis Frath, Christophe Bucher and Thomas Gibaud
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Abstract

Supramolecular crystal gels, a subset of molecular gels, are formed through the self-assembly of low molecular weight gelators into interconnecting crystalline fibers, creating a three-dimensional soft solid network. This study focuses on the formation and properties of viologen-based supramolecular crystalline gels. It aims to answer key questions about the tunability of network properties and the origin of these properties through in-depth analyses of the gelation kinetics triggered by thermal quenching. Experimental investigations, including UV-Vis absorption spectroscopy, rheology, microscopy and scattering measurements, contribute to a comprehensive and self-consistent understanding of the system kinetics. We confirm that viologen-based gelators crystallize by forming nanometer radius hollow tubes that assemble into micro to millimetric spherulites. We then show that crystallization follows the Avrami theory and is based on pre-existing nuclei. We also establish that the growth is interface-controlled, leading the hollow tubes to branch into spherulites with fractal structures. Finally, we demonstrate that the gel properties can be tuned depending on the quenching temperature. Lowering the temperature results in the formation of denser and smaller spherulites. In contrast, the gel's elasticity is not significantly affected by the quench temperature, leading us to hypothesize that the densification of spherulites occurs at the expense of connectivity between spherulites.

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基于 Viologen 的超分子晶体凝胶:凝胶化动力学和对温度的敏感性。
超分子晶体凝胶是分子凝胶的一个分支,它是通过低分子量凝胶体自组装成相互连接的晶体纤维,从而形成三维软固体网络。本研究的重点是基于紫胶的超分子结晶凝胶的形成和特性。研究旨在通过深入分析热淬火引发的凝胶化动力学,回答有关网络特性可调性和这些特性起源的关键问题。包括紫外可见吸收光谱、流变学、显微镜和散射测量在内的实验研究有助于全面、自洽地理解系统动力学。我们证实,紫胶基凝胶剂通过形成纳米半径的空心管结晶,这些空心管组装成微米到毫米级的球形颗粒。然后,我们证明结晶遵循阿夫拉米理论,并以预先存在的晶核为基础。我们还证实,生长是受界面控制的,这导致空心管分支成具有分形结构的球粒。最后,我们证明凝胶特性可根据淬火温度进行调整。降低温度会导致形成密度更大、体积更小的球粒。与此相反,凝胶的弹性并没有受到淬火温度的显著影响,因此我们推测,球形颗粒的致密化是以牺牲球形颗粒之间的连通性为代价的。
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来源期刊
Soft Matter
Soft Matter 工程技术-材料科学:综合
CiteScore
6.00
自引率
5.90%
发文量
891
审稿时长
1.9 months
期刊介绍: Where physics meets chemistry meets biology for fundamental soft matter research.
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