Tunability of the elastocaloric response in main-chain liquid crystalline elastomers

Lavrič, Marta; Derets, Nikita; Črešnar, Dejvid; Cresta, Vanessa; Domenici, Valentina; Rešetič, Andraž; Skačej, Gregor; Sluban, M.; Umek, Polona; Zalar, Boštjan; Kutnjak, Zdravko; Rožič, B.

doi:10.1080/02678292.2020.1786177

Cited by 10 publications

(17 citation statements)

References 43 publications

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“…The liquid crystal-containing elastomers studied in this work undergo a mechanotropic phase transition, from disordered to nematic, which is asssociated with an elastocaloric temperature change of up to ∆T + = 2.9 K. This represents a large improvement over existing reports on the elastocaloric response in other liquid crystalline polymer networks, which typically demonstrate ∆T + ∼ 1 K, 14,22 . Further, these initial results approach the magnitude of the temperature changes of 5.2 and 6.5 K reported for electrocaloric LC systems.…”

Section: Discussionmentioning

confidence: 69%

“…Recent literature reports detail the elastocaloric response of LCEs. Experimental efforts have so far demonstrated elastocaloric temperature changes of only ∆T ∼ 1 K. 14,22 Lavrič et al observed ∆T = 1 K at a strain of ε = 90% and detailed that this ∆T was observed across a range of crosslink density. 22 Skačej has reported molecular simulations that suggest the elastocaloric effect in mainchain LCEs could yield a ∆T > 10 K. 23 However, the simulations underestimate the specific heat of liquid crystal-containing systems, which likely leads to an overestimate of the elastocaloric temperature change.…”

Section: Introductionmentioning

confidence: 99%

“…Experimental efforts have so far demonstrated elastocaloric temperature changes of only ∆T ∼ 1 K. 14,22 Lavrič et al observed ∆T = 1 K at a strain of ε = 90% and detailed that this ∆T was observed across a range of crosslink density. 22 Skačej has reported molecular simulations that suggest the elastocaloric effect in mainchain LCEs could yield a ∆T > 10 K. 23 However, the simulations underestimate the specific heat of liquid crystal-containing systems, which likely leads to an overestimate of the elastocaloric temperature change. LC systems also have been explored as electrocaloric materials, notably harnessing a smectic-to-isotropic transition to achieve a ∆T + of up to 5.2 to 6.5 K. 14,24 Our group has recently quantified the transition from disorder (order parameter Q ≈ 0) to appreciable order (Q ≈ 0.4, i.e., the nematic phase) in a liquid crystal-containing elastomeric network upon application of uniaxial strain.…”

Section: Introductionmentioning

confidence: 99%

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Elastocaloric effect in amorphous polymer networks undergoing mechanotropic phase transitions

Koch,

Herman,

White

2021

Preprint

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Deformations of amorphous polymer networks prepared with significant concentrations of liquid crystalline mesogens have been recently reported to undergo mechanotropic phase transitions. Here, we report that these mechanotropic phase transitions are accompanied by an elastocaloric response (∆T = 2.9 K). Applied uniaxial strain to the elastomeric polymer network transitions the organization of the material from a disordered, amorphous state (order parameter Q = 0) to the nematic phase (Q = 0.47). Both the magnitude of the elastocaloric temperature change and mechanically induced order parameter are dependent on the concentration of liquid crystal mesogens in the material. While the observed temperature changes in these materials are smaller than those observed in shape memory alloys, the responsivity, defined as the temperature change divided by the input stress, is larger by an order of magnitude.

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Section: Discussionmentioning

confidence: 69%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Elastocaloric effect in amorphous polymer networks undergoing mechanotropic phase transitions

Koch,

Herman,

White

2021

Preprint

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“…In recent years, stimulus responsive polymers have become a hotspot in research of advanced functional materials. , One of the most competitive candidates refers to liquid crystalline polymer (LCP), in which the ordered liquid crystal mesogens are frozen by covalently cross-linked polymer network. − Because of the combination of the programmable orientation of liquid crystal and the elasticity of polymer matrix, LCP has been proved as an outstanding matrix to prepare smart actuators and soft robots, presenting great potentials in multiple fields such as biomimetic actuators, artificial muscles, , functional sensors, , and so on. − In order to broaden the practical applications of the LCP materials, various LCP devices with different stimulus responses were prepared, including light, − electricity, , heat, , magnetism, force, and humidity. , …”

Section: Introductionmentioning

confidence: 99%

“…3−7 Because of the combination of the programmable orientation of liquid crystal and the elasticity of polymer matrix, LCP has been proved as an outstanding matrix to prepare smart actuators and soft robots, presenting great potentials in multiple fields such as biomimetic actuators, 8 artificial muscles, 9,10 functional sensors, 11,12 and so on. 13−15 In order to broaden the practical applications of the LCP materials, various LCP devices with different stimulus responses were prepared, including light, 16−19 electricity, 20,21 heat, 22,23 magnetism, 24 force, 25 and humidity. 26,27 Compared with other stimuli, humidity is a nontoxic, harmless trigger that can be easily obtained.…”

Section: Introductionmentioning

confidence: 99%

Reprogrammable Humidity-Driven Liquid Crystalline Polymer Actuator Enabled by Dynamic Ionic Bonds

Wang

Lan

Bao

et al. 2022

ACS Appl. Mater. Interfaces

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Liquid crystalline polymer (LCP) is a promising candidate in the design and fabrication of intelligent soft materials due to the combination of programmable anisotropy and elasticity. Here, a novel strategy to fabricate reprogrammable humidity-responsive LCP materials enabled by dynamic ionic cross-links were put forward. The prepared LCP film deforms reversibly with the change of relative humidity (RH). However, the humidity responsivity loses after soaking the film into CaCl2 solution because of the lock of hygroscopic groups by the formed ionic bonds. By selectively cross-linking specific regions of the LCP film, distinctive humidity-driven motions of the film could be realized. More interestingly, by the EDTA-2K solution treatment, ionic cross-links can be interrupted, leading the LCP film responsive to humidity again. Thanks to feasibly removable ionic cross-links, the humidity-directed soft actuator was totally reprogrammable. The behavior of the novel actuator could be manipulated by either the mesogens alignment or the spatially ionic treatment, providing a feasible but robust strategy to fabricate complex humidity-driven soft robots.

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Electrically Driven Crosslinked Liquid Crystal Polymers^†

Wang,

Jiang,

Yang

2023

Chin. J. Chem.

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Comprehensive SummaryCrosslinked liquid crystal polymers (CLCPs) are smart materials that combine the anisotropy of liquid crystals (LCs) with the elasticity of rubber. When subjected to external stimuli, they exhibit exceptional two‐way shape memory behavior. Among the various stimuli, electrical energy has the advantages of cleanliness, stability, and high controllability; hence, it is widely used for controlling CLCP‐based soft actuators, thus presenting potential for application in diverse, complex scenarios. By combining electrically driven mode and sensor equipment, precise control of CLCPs can be achieved, and the electrically driven CLCPs can accomplish more intricate and sophisticated tasks. This study presents a comprehensive review of electrically driven CLCPs with various driving mechanisms, including the electroclinic effect of ferroelectric CLCPs, the reorganization of LC molecules, the Maxwell effect of dielectric CLCPs, and the Joule heating effect of electrothermally responsive CLCP systems. In addition, a detailed analysis of the applications of electrically driven CLCPs in various research fields is presented. Finally, the current challenges in the field of electrically driven CLCP technology are summarized, along with predictions for future prospects.

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Tunability of the elastocaloric response in main-chain liquid crystalline elastomers

Cited by 10 publications

References 43 publications

Elastocaloric effect in amorphous polymer networks undergoing mechanotropic phase transitions

Elastocaloric effect in amorphous polymer networks undergoing mechanotropic phase transitions

Reprogrammable Humidity-Driven Liquid Crystalline Polymer Actuator Enabled by Dynamic Ionic Bonds

Electrically Driven Crosslinked Liquid Crystal Polymers^†

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Tunability of the elastocaloric response in main-chain liquid crystalline elastomers

Cited by 10 publications

References 43 publications

Elastocaloric effect in amorphous polymer networks undergoing mechanotropic phase transitions

Elastocaloric effect in amorphous polymer networks undergoing mechanotropic phase transitions

Reprogrammable Humidity-Driven Liquid Crystalline Polymer Actuator Enabled by Dynamic Ionic Bonds

Electrically Driven Crosslinked Liquid Crystal Polymers†

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Product

Resources

About

Electrically Driven Crosslinked Liquid Crystal Polymers^†