2023
DOI: 10.3389/frsfm.2023.1123324
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Pattern formation, structure and functionalities of wrinkled liquid crystal surfaces: A soft matter biomimicry platform

Abstract: This review presents an integrated theoretical and computational characterization and analysis of surface pattern formation in chiral and achiral liquid crystal self-assembly and the mechanical/optical/tribological/tissue engineering surface functionalities that emerge from various wrinkling processes. Strategies to target surface patterns include linear, non-linear, multidirectional and multiscale wrinkling phenomena. The focus of the review is to show the unique surface structure-functionalities that emerge … Show more

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Cited by 7 publications
(5 citation statements)
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“…Numerical methods and computational techniques used to solve the various viscoelastic shape equations identify challenges and solutions due to constraints, multiple scales, and self-assembly, including novel nanoparticle crystal-liquid crystal phases, and nematic drops with complex disclinations networks. Essentially all presented results were validated with experimental data 316 and the connections with the soft matter theory/simulation literature were also established so as to build a strong future platform for computational soft matter science. Finally, the outlook section summarizes important future challenges and opportunities in the area of surface pattern formation and dissipative shape evolution.…”
Section: Soft Matter Reviewmentioning
confidence: 85%
“…Numerical methods and computational techniques used to solve the various viscoelastic shape equations identify challenges and solutions due to constraints, multiple scales, and self-assembly, including novel nanoparticle crystal-liquid crystal phases, and nematic drops with complex disclinations networks. Essentially all presented results were validated with experimental data 316 and the connections with the soft matter theory/simulation literature were also established so as to build a strong future platform for computational soft matter science. Finally, the outlook section summarizes important future challenges and opportunities in the area of surface pattern formation and dissipative shape evolution.…”
Section: Soft Matter Reviewmentioning
confidence: 85%
“…This turning point coincides with the dominant resonance peaks (green color of the FTF and STF), which is associated with the mean Maxwell relaxation time. In the range of small and ω ∈ [1,10], there is frequency (green point) where the starts to oscillate and the coupled transfer functions show a multivalued function in the dynamical response. From a mathematical point of view, a plausible explanation of these oscillations deals with the ratio of the Bessel modified function of the first and second it is possible that the system undergoes transitions from real to imaginary roots (See Appendix F for the mathematical details of the complex roots).…”
Section: Flow-stress Loop Diagramsmentioning
confidence: 99%
“…Liquid crystalline organization, structure, and properties are found in a variety of biological systems, whose behavior is specified by complex processes [1,2]. The science of liquid crystal has been used in biological systems such as: (i) plants, (ii) insects, and (iii) membranes and living matter physics [3].…”
Section: Introductionmentioning
confidence: 99%
“…Importantly, possible LC mesogens include rod-, board-, disk-, and screw-like molecules with flexibilities ranging from semi-flexible to rigid, involving monomers or main/side-chain polymers and colloids (Donald et al, 2006;Demus et al, 2008b;Demus et al, 2011). The synthesis and formation of these mesophase materials follow equilibrium self-assembly processes driven by temperature (thermotropic), concentration (lyotropic), or both (Bowick et al, 2017;Wang et al, 2023b). The presence of multiple components, as in nanoparticle-loaded mesophases, gives rise to couplings between self-assembly and phase separation with states that can combine the crystallinity (positional order) of one component with the liquid crystallinity (various degrees of positional and orientational order) of the other (Soulé et al, 2012a;Soulé et al, 2012b;Soulé et al, 2012c;Soule and Rey, 2012;Milette et al, 2013;Gurevich et al, 2014).…”
Section: Introductionmentioning
confidence: 99%
“…Describing the shape using the dimensionless normalized shape coefficient (S) avoids co-mingling properties associated with shape with those associated with curvedness, such as when using the classical differential geometry descriptions based on Gaussian (K), mean (H), and deviatoric (D) curvatures. The shape coefficient-Casorati curvedness (S, C) method has been successfully applied to several soft-matter materials and equilibrium and dissipative processes (Wang et al, 2020;Wang et al, 2022b;Wang et al, 2022a;Wang et al, 2023b). For example, for a saddle point, the classical approach yields K −D 2 .…”
Section: Introductionmentioning
confidence: 99%