Issue 32, 2024

3D visualization reveals the cooling rate dependent crystallization near a wall in dense microgel systems

Abstract

Controlled crystallization, melting and vitrification are important fundamental processes in nature and technology. However, the microscopic details of these fundamental phenomena still lack understanding, in particular how the cooling rate and presence of a wall influence the crystal nucleation and glass formation. Thermoresponsive microgels provide the possibility to study phase transitions at the single-particle level, owing to the ability to tune the particle size with temperature. In this study, we employ composite microgels consisting of a hard core and a crosslinked poly(N-isopropyl acrylamide-co-methacrylic acid) shell to study the crystallization of dense suspensions of soft colloids near a wall using confocal microscopy. We investigate the effect of the cooling rate on the fluid-to-solid transition close to the sample wall. The structures formed during cooling range from glassy in the case of a rapid temperature quench to crystalline when a slow cooling rate is used. Detailed analysis of the final structure reveals that the cooling rate also sets the degree of alignment of the crystal domains with the wall as a result of a balance between homogeneous and heterogeneous crystal nucleation. The results presented here yield valuable insight into the microscopic details of temperature-controlled crystallization near a wall. This understanding will help pave the way towards optimal crystallization conditions for microgel applications.

Graphical abstract: 3D visualization reveals the cooling rate dependent crystallization near a wall in dense microgel systems

Supplementary files

Article information

Article type
Paper
Submitted
30 Apr 2024
Accepted
19 Jun 2024
First published
20 Jun 2024
This article is Open Access
Creative Commons BY license

Soft Matter, 2024,20, 6343-6352

3D visualization reveals the cooling rate dependent crystallization near a wall in dense microgel systems

M. P. M. Schelling, T. W. J. Verouden, T. C. M. Stevens and J.-M. Meijer, Soft Matter, 2024, 20, 6343 DOI: 10.1039/D4SM00517A

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