AI Article Synopsis
- Photoresponsive liquid-crystalline elastomers (LCEs) show potential as soft actuators that can be controlled by light, with their mechanical properties changing under light exposure.
- The study explores how varying stress/strain levels and polymer network characteristics, influenced by solvent amount, affect the performance of LCEs, revealing complex relationships between mechanical behavior and synthesis conditions.
- Results indicate that while increasing solvent reduces certain mechanical properties, it enhances others, and the overall performance peaks at specific operating conditions, which is essential for the design of LCE-based devices.
Article Abstract
Photoresponsive liquid-crystalline elastomers (LCEs) are promising candidates for light-controlled soft actuators. Photoinduced stress/strain originates from the changes in mechanical properties after light irradiation. However, the correlation between the photoinduced mechanical performance and in-use conditions such as stress/strain states and polymer network properties (such as effective crosslink density and dangling chain density) remains unexplored for practical applications. Here, isometric photo-induced stress or isotonic strain is investigated at different operating strains or stresses, respectively, on LCEs with polymer network variations, produced by different amounts of solvent during polymerization. As the solvent volume increases, the moduli and photoinduced stresses decrease. However, the photo-induced strain, fracture strain, fracture stress, and viscosity increase. The optical response performance initially increases with the operating strain/stress, peaks at a higher actuation strain/stress, and then, decreases depending on the polymer network. The maximum work densities, which also depend on the operating stress, are in the range of ≈200-300 kJm. These findings, highlighting the significant variations in the mechanical performance with the operating stress/strain ranges and amount of solvent used in the synthesis, are critical for designing LCE-based mechanical devices.
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| http://dx.doi.org/10.1002/marc.202300709 | DOI Listing |
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