Surface Aligned Main-Chain Liquid Crystalline Elastomers: Tailored Properties by the Choice of Amine Chain Extenders

Yoon, Hyun Jin; Kim, Dae‐Yoon; Jeong, Kwang‐Un; Ahn, Suk‐kyun

doi:10.1021/acs.macromol.7b02514

Cited by 59 publications

(64 citation statements)

References 45 publications

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“…The thermomechanical response of these LCE was examined between 25 and 270 °C (Figure S5, Supporting Information). Actuation of the LCEs is again distinguished from the CnM‐CTA LCE chemistries, which actuate gradually across a wide, relatively low temperature range . In the epoxy‐based LCEs, only 5% strain for all spacer lengths is evident up to 200 °C, followed by a rapid shape change between 200 and 250 °C that results in 20% average strain perpendicular to the director and 40% average strain parallel to the director (Figure e, left).…”

Section: Resultsmentioning

confidence: 97%

Microstructured Photopolymerization of Liquid Crystalline Elastomers in Oxygen‐Rich Environments

McCracken

Tondiglia

Auguste

et al. 2019

Adv Funct Materials

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Liquid crystal elastomers (LCEs) are soft materials that undergo large anisotropic shape change in response to stimuli. Rational organization of the local director field can impart spatial control of the strain profile, enabling stretch-based deformation capable of nearly 20 J kg −1 of output force. LCEs are increasingly being considered in end-use applications in robotics, therapeutics, and optics. Here, a new synthetic approach is introduced to prepare LCEs composed of main chain mesogens via the cationic photopolymerization of the epoxy liquid crystal monomer (LCM). This examination details the optical, mechanical, and thermal properties of epoxide-based LCEs as a function of spacer length (3, 6, or 11 carbons). The oxygen insensitivity of the cationic photopolymerization of these monomers makes this approach particularly attractive for implementation with emerging additive manufacturing techniques. This contribution focuses on microstructuring LCEs via 2-photon direct laser writing (2P-DLW). A custom heated cell facilitated 2P-DLW of the aligned LCE epoxy resin melts to fabricate diverse geometric arrays. Enabled by the orthogonality of the reaction chemistry, hybrid and microstructured material compositions are prepared via the encapsulation of LCE epoxy micropatterns with free-radical polymerization of acrylate-based LCEs. The distinct thermomechanical response of the hybridized and microstructured LCE composites enables local and spatially controlled actuation.

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Section: Resultsmentioning

confidence: 97%

Microstructured Photopolymerization of Liquid Crystalline Elastomers in Oxygen‐Rich Environments

McCracken

Tondiglia

Auguste

et al. 2019

Adv Funct Materials

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“…The procedure of Ahn and co‐workers [ 50 ] was followed with slight modification. RM82, dodecylamine, and 8‐amino‐1‐octanol were combined in a molar ratio of 1.1:0.5:0.5 with 2.5 wt% of Irgacure 651 in a vial and melted at ≈85 °C and vortexed repeatedly.…”

Section: Methodsmentioning

confidence: 99%

“…To fabricate monodomain LCEs, 50 µm thick planar nematic films are synthesized following the work of Ahn and co‐workers (Scheme S1, Supporting Information). [ 50 ] This chemistry is employed due to its amenability to formation of monodomain samples with relatively low nematic‐isotropic transition temperatures ( T NI ) and large thermomechanical strains. Briefly, n ‐dodecylamine and 8‐amino‐1‐octanol are mixed in a 1:1 molar ratio with the diacrylate mesogen RM82 with an overall stoichiometry of acrylate:amine functionalities of 1.1:1, selected to afford a cross‐link density that allows for large strains while maintaining sufficient mechanical robustness.…”

Section: Figurementioning

confidence: 99%

Blueprinting Photothermal Shape‐Morphing of Liquid Crystal Elastomers

et al. 2020

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studies have focused on programming desired 3D structures of soft materials such as shape-memory polymers [2,3] and gels [4][5][6][7] by introducing spatial variations in thermal expansion/contraction, swelling, or molecular order. [8] A particularly useful class of materials to achieve dynamic 2D to 3D shape transformations are liquid crystal elastomers (LCEs), where the coupling between the orientational ordering of polymerized mesogens and the conformation of a polymer backbone can be leveraged for large, anisotropic deformations that are dictated by the director field. [9,10] Using oriented surface alignment layers [11] or microchannels, [12] director orientation can be patterned with a resolution approaching 10 µm. [13] A subsequent reduction of nematic ordering, usually driven by heating, leads to local contraction along the director and expansion along the transverse directions, driving out-of-plane buckling into 3D shapes that are "blueprinted" by the pattern of director orientation. However, while geometric methods allow for the deduction of the necessary inplane director orientation field to generate a desired profile of Gaussian curvature, [14][15][16][17] there are a number of practical drawbacks to this approach. First, prescription of complex director fields requires significant processing, making high-throughput fabrication, and evaluation of designs challenging. Additionally, the surface alignment methods needed to specify director orientation with high spatial resolution are only amenable to certain chemistries due to the need for high mesogen content, and thus cannot be widely generalized to all LCE systems. For example, while classical LCE systems based on siloxanes, [18,19] as well as recently developed systems that rely on simple and efficient "click" chemistries, [20] offer attractive thermal and mechanical properties for shape-morphing systems, they typically only allow for alignment of the director field with coarse spatial resolution such as through application of shear stress [21][22][23] or magnetic fields. [24] To circumvent the need for a spatially varying director orientation, where the direction of deformation varies but the magnitude is constant, a potential alternative method to drive shape changes is to instead locally prescribe the magnitude of deformation within an otherwise homogeneous director field. While spatial variations in the extent of deformation have been widely employed for shape Liquid crystal elastomers (LCEs) are an attractive platform for dynamic shape-morphing due to their ability to rapidly undergo large deformations. While recent work has focused on patterning the director orientation field to achieve desired target shapes, this strategy cannot be generalized to material systems where high-resolution surface alignment is impractical. Instead of programming the local orientation of anisotropic deformation, an alternative strategy for prescribed shape-morphing by programming the magnitude of stretch ratio in a thin LCE sheet with constant director orientation is...

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“…More recently, extensive studies on LCE synthesis have been reported based on diacrylate-, divinyl-, or diglycidyl-functionalized LC monomers (so-called reactive mesogens). These monomers can first be chain-extended using alkyl dithiols [19][20][21][22][23][24][25][26][27][28], alkyl amines [29][30][31], or alkyl dicarboxylic acids [32,33], and then they can be crosslinked in the presence or absence of multifunctional crosslinkers to obtain main-chain LCEs. One of the major advantages of the above-mentioned method is that various LC alignment methods can be integrated during LCE synthesis.…”

Section: Introductionmentioning

confidence: 99%

“…As separately demonstrated by the research groups of Ware [37] and Yakacki [38], crystallizable LCEs not only increase the mechanical properties, including stiffness and toughness, but also enhance the blocking stress and work capacity of thiol-acrylate LCEs. Recently, our group also reported that the glass transition temperature and mechanical properties of main-chain LCEs can be effectively manipulated by adjusting the length of the alkyl groups in the primary amine chain extenders, which can systematically alter the actuation temperature [30]. Based on interpenetrating LCE architectures, Yang et al achieved enormous blocking stress (2.53 MPa) and work capacity (1267.7 kJ/m 3 ), which are 7 and 31 times larger than those of skeletal muscles (0.35 MPa and 40 kJ/m 3 ), respectively.…”

Section: Introductionmentioning

confidence: 99%

Effect of Isomeric Amine Chain Extenders and Crosslink Density on the Properties of Liquid Crystal Elastomers

et al. 2020

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Among the various types of shape changing materials, liquid crystal elastomers (LCEs) have received significant attention as they can undergo programmed and reversible shape transformations. The molecular engineering of LCEs is the key to manipulating their phase transition, mechanical properties, and actuation performance. In this work, LCEs containing three different types of butyl groups (n-, iso-, and sec-butyl) in the side chain were synthesized, and the effect of isomeric amine chain extenders on the thermal, mechanical, and actuation properties of the resulting LCEs was investigated. Because of the considerably low reactivity of the sec-butyl group toward the diacrylate in the LC monomer, only a densely crosslinked LCE was synthesized. Most interestingly, the mechanical properties, actuation temperature, and blocking stress of the LCEs comprising isobutyl groups were higher than those of the LCEs comprising n-butyl groups. This difference was attributed to the presence of branches in the LCEs with isobutyl groups, which resulted in a tighter molecular packing and reduced the free volume. Our results suggest a facile and effective method for synthesizing LCEs with tailored mechanical and actuation properties by the choice of chain extenders, which may advance the development of soft actuators for a variety of applications in aerospace, medicine, and optics.

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Surface Aligned Main-Chain Liquid Crystalline Elastomers: Tailored Properties by the Choice of Amine Chain Extenders

Cited by 59 publications

References 45 publications

Microstructured Photopolymerization of Liquid Crystalline Elastomers in Oxygen‐Rich Environments

Microstructured Photopolymerization of Liquid Crystalline Elastomers in Oxygen‐Rich Environments

Blueprinting Photothermal Shape‐Morphing of Liquid Crystal Elastomers

Effect of Isomeric Amine Chain Extenders and Crosslink Density on the Properties of Liquid Crystal Elastomers

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