Interlocking-interface-enabled thermally deformable liquid metal/polymer membrane with high bonding strength

A universal method to fabricate LM membrane on multiple polymeric substrates based on interlocking interface has been proposed, which improves interfacial compatibility and introduces strong binding between LM and the polymer substrate. The LM membrane could be used to construct soft phothothermal a...

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Bibliographic Details
Published in:Journal of colloid and interface science 2023-02, Vol.631, p.78-88
Main Authors: Liu, Tian-Ying, Jia, Fan, Li, Qian, Liu, Li, Gao, Jian-Ye, Li, Dong-Dong, Wang, Qian, Liu, Jing
Format: Article
Language:English
Subjects:
Interfacial compatibility
Interlocking interface
Liquid metal membrane
Photothermal actuation
Polymer composite
Surface processing
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Summary:A universal method to fabricate LM membrane on multiple polymeric substrates based on interlocking interface has been proposed, which improves interfacial compatibility and introduces strong binding between LM and the polymer substrate. The LM membrane could be used to construct soft phothothermal actuators. [Display omitted] The high surface tension of liquid metal (LM) causes interface incompatibility and poor bonding strength with many substrates. Fine adjustment towards the properties of the surface area is sufficient to introduce strong bonding. Hence, we hypothesize that the interlocking structure using hydrophilic polyvinyl alcohol (PVA) as a “bridge” should be helpful for tight interfacial bonding of LM with polymeric substrates, thus achieving high-performance LM/polymer membranes, which have wide applications in the field of soft sensors and robotics. The bulk EGaIn was fabricated into LM nanoparticles (LMNPs@PVA) solution. Then, PVA molecules were “doped” into the surface crosslink of the plasma treated polymer substrate by an interfacial penetrating method. Afterward, the solution was evenly dropped on the surface of the treated substrate to obtain the LMNP/polymer membrane after the water evaporated. Photothermal actuators were fabricated based on the membranes. During the interlocking structure, PVA macromolecules could be doped and trapped onto the top surfaces of various polymer substrates as binding “bridges” between the LMNPs and the matrix materials. The achieved LMNP membrane exhibites satisfactory bonding strength, durability and water-assisted erase-reprint, which can be used as soft photothermal actuators with remote laser control.
ISSN:0021-9797
1095-7103
DOI:10.1016/j.jcis.2022.10.134