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Liquid‐Crystal‐Elastomer‐Based Dissipative Structures by Digital Light Processing 3D Printing

Nicholas A. Traugutt, Devesh Mistry, Chaoqian Luo, Kai Yu, Qi Ge, Christopher M. Yakacki

2020Advanced Materials239 citationsDOIOpen Access PDF

Abstract

Digital Light Processing (DLP) 3D printing enables the creation of hierarchical complex structures with specific micro- and macroscopic architectures that are impossible to achieve through traditional manufacturing methods. Here, this hierarchy is extended to the mesoscopic length scale for optimized devices that dissipate mechanical energy. A photocurable, thus DLP-printable main-chain liquid crystal elastomer (LCE) resin is reported and used to print a variety of complex, high-resolution energy-dissipative devices. Using compressive mechanical testing, the stress-strain responses of 3D-printed LCE lattice structures are shown to have 12 times greater rate-dependence and up to 27 times greater strain-energy dissipation compared to those printed from a commercially available photocurable elastomer resin. The reported behaviors of these structures provide further insight into the much-overlooked energy-dissipation properties of LCEs and can inspire the development of high-energy-absorbing device applications.

Topics & Concepts

Materials scienceElastomerDissipative systemDigital Light Processing3D printingLiquid crystalInkwellPolymer scienceNanotechnologyComposite materialOptoelectronicsOpticsQuantum mechanicsProjectorPhysicsAdvanced Materials and MechanicsAdvanced Sensor and Energy Harvesting MaterialsPolymer composites and self-healing
Liquid‐Crystal‐Elastomer‐Based Dissipative Structures by Digital Light Processing 3D Printing | Litcius