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Solutal-buoyancy-driven intertwining and rotation of patterned elastic sheets.

Authors :
Manna RK
Shklyaev OE
Stone HA
Balazs AC
Source :
PNAS nexus [PNAS Nexus] 2022 Jun 08; Vol. 1 (2), pp. pgac072. Date of Electronic Publication: 2022 Jun 08 (Print Publication: 2022).
Publication Year :
2022

Abstract

The intertwining of strands into 3D spirals is ubiquitous in biology, enabling functions from information storage to maintenance of cell structure and directed locomotion. In synthetic systems, entwined fibers can provide superior mechanical properties and act as artificial muscle or structural reinforcements. Unlike structures in nature, the entwinement of synthetic materials typically requires application of an external stimulus, such as mechanical actuation, light, or a magnetic field. Herein, we use computational modeling to design microscale sheets that mimic biology by transducing chemical energy into mechanical action, and thereby self-organize and interlink into 3D spirals, which spontaneously rotate. These flexible sheets are immersed in a fluid-filled microchamber that encompasses an immobilized patch of catalysts on the bottom wall. The sheets themselves can be passive or active (coated with catalyst). Catalytic reactions in the solution generate products that occupy different volumes than the reactants. The resulting density variations exert a force on the fluid (solutal buoyancy force) that causes motion, which in turn drives the interlinking and collective swirling of the sheets. The individual sheets do not rotate; rotation only occurs when the sheets are interlinked. This level of autonomous, coordinated 3D structural organization, intertwining, and rotation is unexpected in synthetic materials systems operating without external controls. Using physical arguments, we identify dimensionless ratios that are useful in scaling these ideas to other systems. These findings are valuable for creating materials that act as "machines", and directing soft matter to undergo self-sustained, multistep assembly that is governed by intrinsic chemical reactions.<br /> (© The Author(s) 2022. Published by Oxford University Press on behalf of the National Academy of Sciences.)

Details

Language :
English
ISSN :
2752-6542
Volume :
1
Issue :
2
Database :
MEDLINE
Journal :
PNAS nexus
Publication Type :
Academic Journal
Accession number :
36713315
Full Text :
https://doi.org/10.1093/pnasnexus/pgac072