The Contribution of Oligomerization Reaction Chemistry to the Thermomechanical Properties of Surface-Aligned Liquid Crystalline Elastomers

Hebner, Tayler S.; McCracken, Joselle M.; Bowman, Christopher N.; White, Timothy J.

doi:10.1021/acs.macromol.2c02371

Cited by 4 publications

(6 citation statements)

References 27 publications

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“…The orientation parameter was calculated from the azimuthal intensity profile (via eqs and ) and ranged from 0.51 to 0.56 (see Table S3). These values confirm strong nematic alignment similar to values reported in other LCEs prepared by surface alignment. ,,, …”

Section: Results and Discussionsupporting

confidence: 88%

“…These values confirm strong nematic alignment similar to values reported in other LCEs prepared by surface alignment. 16,24,27,28 The microstructure is evident in the polarized micrographs with regular striation normal to the direction of alignment (Figures 3C and S4). Further, the wide-angle X-ray scattering (WAXS) pattern in Figure 3B contains multiple faint, diffuse arcs at smaller angles, indicating additional liquid crystalline ordering.…”

Section: ■ Results and Discussionmentioning

confidence: 98%

“…However, the polymer network formation is heterogeneous, which is evident in distinctive mechanical properties . We have recently demonstrated that adjustment to the kinetics (with comparatively slow base catalysts) of the thiol-Michael addition reaction to prepare oligomeric species can produce aligned LCEs via surface anchoring. , However, as with LCEs prepared by aza-Michael addition reactions, the oligomerization reaction can occur over hours and limits the throughput of the LCE sample preparation.…”

Section: Introductionmentioning

confidence: 99%

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Liquid Crystal Elastomers Prepared by Thiol–Ene Photopolymerization Amenable to Surface-Enforced Alignment

Fowler,

Pearl,

Hoang

et al. 2024

Macromolecules

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Liquid crystal elastomers (LCEs) assimilate the anisotropy of liquid crystalline phases with the rubber elasticity of polymer networks. Numerous recent reports detail the preparation of LCEs by sequential chain extension reactions of diacrylate liquid crystalline monomers followed by the photopolymerization of liquid crystalline oligomers. While these reactions are widely utilized, sample fabrication can take hours or even days. Other reports detail the preparation of LCEs via direct thiol−acrylate photopolymerization via free radical chain transfer reactions. While this is a rapid and straightforward approach to preparing LCEs, the topology of the polymer network composition is heterogeneous, with wide variance in molecular weight between cross-links and extensive prevalence of pendant groups. Here, we detail the preparation of LCEs via thiol−ene photopolymerization. The compositions introduced here are amenable to surface-enforced alignment, which enables the high-fidelity inscription of complex director profiles. Compared to prior thiol-based LCE compositions, direct preparation of LCE by thiol−ene photopolymerization is rapid, forms largely homogeneous polymer networks, and has wide tunability in cross-link density.

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Section: Results and Discussionsupporting

confidence: 88%

Section: ■ Results and Discussionmentioning

confidence: 98%

Section: Introductionmentioning

confidence: 99%

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Liquid Crystal Elastomers Prepared by Thiol–Ene Photopolymerization Amenable to Surface-Enforced Alignment

Fowler,

Pearl,

Hoang

et al. 2024

Macromolecules

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“…As a starting point, we canvased the literature for Young's modulus values of LCEs aligned by surfaceanchoring. [48][49][50][51][52] In particular, we isolate Young's modulus perpendicular to the direction of alignment (i.e., the direction of electromechanical deformation) as well as Young's modulus contrast (i.e., the ratio of the parallel and perpendicular Young's modulus) as representations of mechanical anisotropy. This analysis is summarized in Figure 2.…”

Section: Doi: 101002/admt202301970mentioning

confidence: 99%

Enhanced Electromechanical Output in Liquid Crystal Elastomers Prepared by Thiol‐ene Photopolymerization

Fowler,

Pearl,

White

2024

Adv Materials Technologies

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The electrically‐directed, isothermal response of liquid crystal elastomers (LCEs) to an applied electric field is a compelling approach to realize spatially tailorable, sequence‐controllable, and high‐frequency deformation. The electromechanical response is facilitated by coating aligned LCEs with compliant electrodes. Upon application of an electric field, the electrodes attract and generate Maxwell stress. The directional difference in moduli for aligned LCEs produces directional deformation of the material and does not require mechanical bias or framing. Here, LCEs prepared from a newly reported thiol‐ene reaction are explored as DEAs with improved mechanical and dielectric properties. This report details that incorporating a difunctional liquid crystalline monomer composed of allyl ether functional groups reduces Young's modulus, increases the dielectric constant, and improves cyclic recovery compared to an analogous LCE prepared by thiol‐ene polymerization. Electrically‐induced, isothermal deformation of as much as 30% strain is reported. The facile chemistry and enhanced electromechanical response reported here may enable the functional integration of LCEs in applications such as robotics.

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“…It should be noted that a primary amine group can react with two acrylate functionalities, while a secondary amine can only react with one acrylate moiety, with primary amines reacting faster than secondary amines for this reaction, as demonstrated earlier. 49,50 An index of 100 refers to a 1:1 ratio where every primary and secondary amine can in principle react with an acrylate functionality (2 mol of acrylates per 1 mol of amines), which constitutes a perfect network structure. Deviation of this index to either side will lead to a decrease in the cross-link density.…”

Section: ■ Introductionmentioning

confidence: 99%

Enhanced Viscosity Control in Thermosets Derived from Epoxy and Acrylate Monomers Based on Thermoreversible Aza-Michael Chemistry

Engelen,

Van Lijsebetten,

Aksakal

et al. 2023

Macromolecules

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Epoxies, epoxy acrylates, and acrylic resins account for a large portion of the thermoset market, yet their inherently highly cross-linked nature prevents them from being reprocessed or recycled. Herein, we present a simple reversible epoxy-based curing strategy that can address these issues. First, an epoxy monomer is ring-opened with ammonia to result in β-hydroxyamines through a straightforward and scalable synthesis that we have demonstrated on multiple examples. The epoxy-derived amines are then cured with bisacrylates, creating dynamic covalent β-amino ester crosslinkages through a thermoreversible aza-Michael reaction. The resulting networks show a very pronounced drop in viscosity in the temperature region of 150−180 °C, which we were able to attribute mainly to significant de-cross-linking of the amine and acrylate moieties, rather than to activation of dynamic ester bond exchanges. Nevertheless, the materials do not fully liquify and retain their structural integrity as a result of the very fast amine-acrylate rebonding kinetics. As a result, cross-linked epoxy-based materials could be obtained with simultaneously enhanced (re)processability at high temperatures and strongly inhibited deformation at lower temperatures (<120 °C). The protocol is demonstrated for both petrochemically based building blocks (such as bisphenol A), as well as for fully biobased compounds (vanillin-epoxy and a Velvetol-based bisacrylate), showing its versatility. As a result of the widespread use of epoxy resins, the ease of implementation, and its interesting temperature window for debonding/ rebonding, industrial applications can be foreseen for this thermoreversible curing strategy.

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The Contribution of Oligomerization Reaction Chemistry to the Thermomechanical Properties of Surface-Aligned Liquid Crystalline Elastomers

Cited by 4 publications

References 27 publications

Liquid Crystal Elastomers Prepared by Thiol–Ene Photopolymerization Amenable to Surface-Enforced Alignment

Liquid Crystal Elastomers Prepared by Thiol–Ene Photopolymerization Amenable to Surface-Enforced Alignment

Enhanced Electromechanical Output in Liquid Crystal Elastomers Prepared by Thiol‐ene Photopolymerization

Enhanced Viscosity Control in Thermosets Derived from Epoxy and Acrylate Monomers Based on Thermoreversible Aza-Michael Chemistry

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