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High Thermal Conductive Liquid Crystal Elastomer Nanofibers

Jingxuan Wang, Yue Wen, Duo Pan, Shulang Lin, Amutha Chinnappan, Qiguang He, Chuntai Liu, Zhiwei Huang, Shengqiang Cai, Seeram Ramakrishna, Sunmi Shin

2024Nano Letters12 citationsDOI

Abstract

Liquid crystal elastomers (LCEs), consisting of polymer networks and liquid crystal mesogens, show a reversible phase change under thermal stimuli. However, the kinetic performance is limited by the inherently low thermal conductivity of the polymers. Transforming amorphous bulk into a fiber enhances thermal conductivity through the alignment of polymer chains. Challenges are present due to their rigid networks, while cross-links are crucial for deformation. Here, we employ hydrodynamic alignment to orient the LCE domains assisted by controlled in situ cross-linking and to remarkably reduce the diameter to submicrons. We report that the intrinsic thermal conductivity of LCE fibers at room temperature reaches 1.44 ± 0.32 W/m-K with the sub-100 nm diameter close to the upper limit determined in the quasi-1D regime. Combining the outstanding thermal conductivity and thin diameters, we anticipate these fibers to exhibit a rapid response and high force output in thermomechanical systems. The fabrication method is expected to apply to other cross-linked polymers.

Topics & Concepts

Materials scienceThermal conductivityElastomerPolymerLiquid crystalComposite materialAmorphous solidFabricationThermalElectrical conductorFiberNanotechnologyOptoelectronicsCrystallographyThermodynamicsChemistryAlternative medicinePathologyMedicinePhysicsAdvanced Materials and MechanicsAdvanced Sensor and Energy Harvesting MaterialsLiquid Crystal Research Advancements