Highly Durable and Tough Liquid Crystal Elastomers

The network structures of liquid crystal elastomers (LCEs) are crucial to impart rubbery behavior to LCEs and enable reversible actuation. Most LCEs developed to date are covalently linked, implying that the cross-links are fixed at a particular position. Herein, we report a new class of LCEs integrating polyrotaxanes (PRs) as slidable cross-links (PR-LCEs). Interestingly, the incorporation of a low loading (0.3–2.0 wt %) of the PR cross-linkers to the LCE causes a significant impact on various properties of the resulting PR-LCEs due to the pulley effect. The optimum PR loading is determined to be 0.5 wt %, at which point the toughness and damping behavior are maximized. The robust mechanical properties of the PR-LCE offers a superior actuation performance to that of the pristine LCE along with an excellent quadruple shape-memory effect. Furthermore, the incorporation of PR is useful to enhance the efficiency of shape-memory-assisted self-healing when heating above the nematic–isotropic transition.

Section: Introductionmentioning

confidence: 99%

Slidable Cross-Linking Effect on Liquid Crystal Elastomers: Enhancement of Toughness, Shape-Memory, and Self-Healing Properties

Choi

Kim

Park

et al. 2022

“…LCE materials generating higher blocking stress have been reported. To our knowledge, there are no reported LCEs capable of generating this high blocking stress at such low temperature values and over such a narrow temperature range. ,,, Actuation strain of an unconstrained semicrystalline LCE sample was also measured using an iso-force test (Figure C). On heating up to 50 °C, LCE films exhibit an actuation strain (contraction) of 0.56 ± 0.07% along the nematic director.…”

Section: Resultsmentioning

confidence: 99%

“…Cross-link density can also be increased to increase the elastic modulus of the material, but this approach greatly compromises the magnitude of the stimulus response the system can exhibit . Interpenetrating liquid crystalline polymer networks have been developed that significantly enhance the mechanical properties of the LCE. − Taking advantage of this approach, Yang and co-workers reported on interpenetrating polymer networks to achieve a blocking stress of 2.53 MPa and work capacity of 1267.7 kJ/m 3 . Inducing semicrystallinity in LCEs is another approach to enhance stiffness and achieve tough, higher-performance LCEs. ,− Kim et al reported on a crystallizable thiol–acrylate LCE material with blocking stress and actuation work capacity of 1.3 MPa and 730.5 kJ/m 3 , respectively .…”

Section: Introductionmentioning

confidence: 99%

Programmable Shape Change in Semicrystalline Liquid Crystal Elastomers

Javed

Corazao

Saed

et al. 2022

Liquid crystal elastomers (LCEs) are stimuli-responsive materials capable of reversible and programmable shape change in response to an environmental stimulus. Despite the highly responsive nature of these materials, the modest elastic modulus and blocking stress exhibited by these actuating materials can be limiting in some engineering applications. Here, we engineer a semicrystalline LCE, where the incorporation of semicrystallinity in a lightly cross-linked liquid crystalline network yields tough and highly responsive materials. Directed self-assembly can be employed to program director profiles through the thickness of the semicrystalline LCE. In short, we use the alignment of a liquid crystal monomer phase to pattern the anisotropy of a semicrystalline polymer network. Both the semicrystalline-liquid crystalline and liquid crystalline−isotropic phase transition temperatures provide controllable shape transformations. A planarly aligned sample's normalized dimension parallel to the nematic director decreases from 1 at room temperature to 0.42 at 250 °C. The introduction of the semicrystalline nature also enhances the mechanical properties exhibited by the semicrystalline LCE. Semicrystalline LCEs have a storage modulus of 390 MPa at room temperature, and monodomain samples are capable of generating a contractile stress of 2.7 MPa on heating from 25 to 50 °C, far below the nematic to isotropic transition temperature. The robust mechanical properties of this material combined with the high actuation strain can be leveraged for applications such as soft robotics and actuators capable of doing significant work.

“…In addition, constructing an interpenetrating network (IPN) structure is considered another effective strategy to improve the mechanical properties of gel materials. 29 Compared with fully interpenetrating networks, semi-interpenetrating network (semi-IPN) gels can provide a fast response to environmental stimuli and higher tensile properties due to the absence of restricted interpenetrating elastic networks. 30 Consequently, it is worth exploring how to introduce PU and semi-IPN structures into the ionogel system to effectively enhance the mechanical performance and durability.…”

Section: ■ Introductionmentioning

confidence: 99%

Mechanically Strong, Wet Adhesive, and Self-Healing Polyurethane Ionogel Enhanced with a Semi-interpenetrating Network for Underwater Motion Detection

Wang

Xiao

et al. 2022

The gel-based sensors have developed rapidly in recent years toward multifunctionality. However, there are still some challenges that need to be solved, such as poor mechanical properties and inaccessibility to wet or water environments. To address these issues, we have developed an ionogel with a semi-interpenetrating network structure by adopting poly(vinylidene fluoride-co-hexafluoropropylene) as the linear non-cross-linked network, a double-bonded ionic liquid and double-bonded capped polyurethane as the cross-linked network, and an ionic liquid as the conductive media. The obtained ionogel exhibits tunable mechanical properties (3.67–8.76 MPa) and excellent sensing properties (IG-20, GF = 8.2). The superb environmental stability and self-healing properties of the ionogel were also demonstrated. Meanwhile, adhesion, self-healing, and sensing performance were guaranteed for underwater due to the presence of a large number of C–F bonds. We strongly believe that this ionogel with excellent mechanical properties and underwater communication is expected for monitoring the health of the human body and information transmission in the future.