Regression analysis for predicting the elasticity of liquid crystal elastomers

Doi, Hideo; Takahashi, Kazuaki Z.; Yasuoka, Haruka; Fukuda, Jun Ichi; Aoyagi, Takeshi

doi:10.1038/s41598-022-23897-0

Cited by 3 publications

(3 citation statements)

References 68 publications

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“…As an actuator whose mechanical properties can be tuned by changing just its chemical composition, [1,[9][10][11][12][13] these lightresponsive liquid crystalline-based materials are attractive materials, acting either as a standalone actuator or as integrated into a system. [6,14] One significant challenge for developing novel and advanced applications with these materials is the lack of a basic understanding of the chemistry and physics of these materials, as well as their responses to the applied stimuli, and eventually how this information can be used to yield a certain mechanical performance.…”

Section: Introductionmentioning

confidence: 99%

Understanding Photomechanical Behavior of Liquid Crystalline‐Based Actuators

Lall

Zappe

2023

Macro Materials & Eng

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Liquid crystalline‐based actuators containing azobenzene photoswitches have been used to demonstrate light‐responsive motion in soft actuator systems. Understanding the mechanical performance of these light‐responsive actuators as a function of the polymer chemistry as well as the nature and concentration of the photoswitches is crucial for developing advanced applications. A systematic study is presented here that clarifies the role of azobenzene photoswitches and the liquid crystalline networks in generating the desired photomechanical performance. Through measurement of photo stimulated mechanical behavior, in particular generated force and strain, a generalized set of guidelines concerning the appropriate subset of polymer chemistry and photoswitches required to achieve the desired performance for actuator design is derived.

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Section: Introductionmentioning

confidence: 99%

Understanding Photomechanical Behavior of Liquid Crystalline‐Based Actuators

Lall

Zappe

2023

Macro Materials & Eng

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“…It is worth noting that while generic descriptors can be inadequate, there have been attempts to tailor descriptors specifically for elastomers to predict their mechanical properties. To date, accurately predicting the mechanical properties of elastomers requires descriptors derived from molecular structures, simulations, and/or experimental data. − Descriptors based on molecular structures typically originate from the monomers comprising the elastomers, providing insight into their physicochemical features and stoichiometry. − Descriptors based on numerical simulation, such as electronic parameters (e.g., HOMO/LUMO gap, polarizability) from density functional theory, , thermodynamic parameters from thermodynamic models, elongation simulation data from molecular dynamics, and chain architecture from Monte Carlo simulations, provide crucial information about intermolecular interactions. Descriptors based on experiments, such as FT-IR absorbance, can be utilized to gauge the degree of cross-linking. , Although these descriptors, when combined, provide a comprehensive characterization of elastomers, their dependence on simulation and experimental data limits the applicability of HTS in an elastomer system, as acquiring experimental data or conducting complex simulations for all candidates of interest is often not feasible.…”

Section: Introductionmentioning

confidence: 99%

“…32−36 Descriptors based on molecular structures typically originate from the monomers comprising the elastomers, providing insight into their physicochemical features and stoichiometry. 32−36 Descriptors based on numerical simulation, such as electronic parameters (e.g., HOMO/LUMO gap, polarizability) from density functional theory, 33,35 thermodynamic parameters from thermodynamic models, 35 elongation simulation data from molecular dynamics, 34 and chain architecture from Monte Carlo simulations, 32 provide crucial information about intermolecular interactions. Descriptors based on experiments, such as FT-IR absorbance, can be utilized to gauge the degree of cross-linking.…”

Section: Introductionmentioning

confidence: 99%

Structure-Based Multilevel Descriptors for High-throughput Screening of Elastomers

Deng,

Chen,

et al. 2023

J. Phys. Chem. B

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To discover new materials, high-throughput screening (HTS) with machine learning (ML) requires universally available descriptors that can accurately predict the desired properties. For elastomers, experimental and simulation data in current descriptors may not be available for all candidates of interest, hindering elastomer discovery through HTS. To address this challenge, we introduce structure-based multilevel (SM) descriptors of elastomers derived solely from molecular structure that is universally available. Our SM descriptors are hierarchically organized to capture both local soft and hard segment structures as well as the global structures of elastomers. With the SM-Morgan Fingerprint (SM-MF) descriptor, one of our SM descriptors, a machine learning model accurately predicts elastomer toughness with a remarkable accuracy of 0.91. Furthermore, an HTS pipeline is established to swiftly screen elastomers with targeted toughness. We also demonstrate the generality and applicability of SM descriptors by using them to construct HTS pipelines for screening elastomers with a targeted critical strain or Young's modulus. The user-friendliness and low computational cost of SM descriptors make them a promising tool to significantly enhance HTS in the search for novel materials.

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