Wet spinning of the graphene oxide composite liquid crystals toward graded utilization of waste heat

Thermal conductive composite materials (TCCMs) applied in the thermal management are of ever-rising significance with the rapid development of a variety of thermal-related industrial products. Previously, the demand for TCCMs with differential thermal conductivity is generally met by using two strat...

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Veröffentlicht in:	Journal of materials science 2022, Vol.57 (4), p.2528-2539
Hauptverfasser:	Ye, Zhenda, Zhao, Xi, Yu, Weitai, Chen, Ying, Lin, Pengcheng
Format:	Artikel
Sprache:	eng
Schlagworte:	Backup software Calcium alginate Characterization and Evaluation of Materials Chemical reactions Chemical reduction Chemistry and Materials Science Classical Mechanics Composite materials Composites & Nanocomposites Composition Crystallography and Scattering Methods Electric properties Electronic devices Energy storage Fibers Force and energy Graphene Graphite Heat conductivity Heat storage Heat transfer Industrial development Lime Liquid crystals Materials Science Miscibility Optical measuring instruments Polymer Sciences Sensors Solid Mechanics Spinning (materials) Supply and demand Tensile strength Thermal conductivity Thermal energy Thermal management Waste heat recovery Waste utilization Wet spinning
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container_title	Journal of materials science
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creator	Ye, Zhenda Zhao, Xi Yu, Weitai Chen, Ying Lin, Pengcheng
description	Thermal conductive composite materials (TCCMs) applied in the thermal management are of ever-rising significance with the rapid development of a variety of thermal-related industrial products. Previously, the demand for TCCMs with differential thermal conductivity is generally met by using two strategies, tuning the material composition and designing the composite microstructure. However, the miscibility between different components is usually poor, resulting in the uniformity of thermal conductivity of TCCMs. In this work, the flexible reduced graphene oxide@calcium alginate (RGO@CA) composite fibers are fabricated by wet spinning of the lyotropic graphene oxide composite liquid crystals and wet chemical reduction. The resulted RGO@CA composite fibers exhibit high tensile strength of about 200 MPa. The graded utilization of the waste heat can be realized by using RGO@CA composite fibers with different compositions. The displayed utilizations of the waste heat include thermal energy storage, optical sensor, thermal source for chemical reaction. The proposed liquid crystal spinning demonstrates a novel strategy for developing advanced materials toward the thermal management and waste heat recovery of electronic devices and systems. Graphical abstract
doi_str_mv	10.1007/s10853-021-06662-y
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The proposed liquid crystal spinning demonstrates a novel strategy for developing advanced materials toward the thermal management and waste heat recovery of electronic devices and systems. 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Previously, the demand for TCCMs with differential thermal conductivity is generally met by using two strategies, tuning the material composition and designing the composite microstructure. However, the miscibility between different components is usually poor, resulting in the uniformity of thermal conductivity of TCCMs. In this work, the flexible reduced graphene oxide@calcium alginate (RGO@CA) composite fibers are fabricated by wet spinning of the lyotropic graphene oxide composite liquid crystals and wet chemical reduction. The resulted RGO@CA composite fibers exhibit high tensile strength of about 200 MPa. The graded utilization of the waste heat can be realized by using RGO@CA composite fibers with different compositions. The displayed utilizations of the waste heat include thermal energy storage, optical sensor, thermal source for chemical reaction. The proposed liquid crystal spinning demonstrates a novel strategy for developing advanced materials toward the thermal management and waste heat recovery of electronic devices and systems. 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subjects	Backup software Calcium alginate Characterization and Evaluation of Materials Chemical reactions Chemical reduction Chemistry and Materials Science Classical Mechanics Composite materials Composites & Nanocomposites Composition Crystallography and Scattering Methods Electric properties Electronic devices Energy storage Fibers Force and energy Graphene Graphite Heat conductivity Heat storage Heat transfer Industrial development Lime Liquid crystals Materials Science Miscibility Optical measuring instruments Polymer Sciences Sensors Solid Mechanics Spinning (materials) Supply and demand Tensile strength Thermal conductivity Thermal energy Thermal management Waste heat recovery Waste utilization Wet spinning
title	Wet spinning of the graphene oxide composite liquid crystals toward graded utilization of waste heat
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