Harnessing osmotic swelling stress for robust hydrogel actuators

The volumetric expansion of hydrogels driven by osmotic swelling stress has enabled hydrogel actuators for myriad applications. However, most existing studies disregard optimizing the osmotic swelling stress for powerful actuation and simply utilize the osmotic swelling stress to trigger certain mod...

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Bibliographic Details
Published in:Soft matter 2022-07, Vol.18 (28), p.5177-5184
Main Authors: He, Xitao, Zhu, Jie, Yang, Canhui
Format: Article
Language:English
Subjects:
Actuation
Actuators
Constraints
Hydrogels
Optimization
Osmosis
Polyacrylamide
Rabbits
Robustness
Stress
Swelling
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Summary:The volumetric expansion of hydrogels driven by osmotic swelling stress has enabled hydrogel actuators for myriad applications. However, most existing studies disregard optimizing the osmotic swelling stress for powerful actuation and simply utilize the osmotic swelling stress to trigger certain modes of actuation. In this work, we probe the osmotic swelling stress of hydrogels using polyacrylamide as a model system. We design and perform constrained swelling experiments to measure the osmotic swelling stresses at different levels of constraint and compare the results to the theoretical predictions based on the Flory-Huggins model. We optimize the osmotic swelling properties by tuning the constituents and structures of the hydrogel and achieve an enhancement of the magnitude of actuation stress from ∼180 kPa to ∼400 kPa. As a proof of concept, we demonstrate a robust hydrogel jack that can lift a weight 2000 times its own weight by harnessing the high osmotic swelling stress. The feasibility and limits of harnessing the osmotic swelling stress of hydrogels for actuation are discussed. The swelling of a hydrogel can exert enormous osmotic swelling stress, which can be harnessed to achieve robust hydrogel actuators. A hydrogel jack that can lift a weight 2000 times its own weight is demonstrated.
ISSN:1744-683X
1744-6848
DOI:10.1039/d2sm00591c