Electric Current Aligning Component Units during Graphene Fiber Joule Heating

Joule heating is featured with an extremely high rising rate of temperature with hundreds of kelvin per second, which has shown superiorities of high efficiency and energy conservation in graphene fabrication. Herein, we design a dynamic joule heating system for continuous synthesis of graphene fibe...

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Veröffentlicht in:	Advanced functional materials 2022-03, Vol.32 (11), p.n/a
Hauptverfasser:	Cheng, Yi, Cui, Guang, Liu, Changhao, Liu, Zhetong, Yan, Longge, Liu, Bingyao, Yuan, Hao, Shi, Pengcheng, Jiang, Jun, Huang, Kewen, Wang, Kun, Cheng, Shuting, Li, Junliang, Gao, Peng, Zhang, Xinfang, Qi, Yue, Liu, Zhongfan
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Sprache:	eng
Schlagworte:	component units conformation order Continuous fibers electric current aligning Electric fields Energy consumption Free energy Graphene graphene fibers joule heating Materials science Ohmic dissipation Resistance heating Sheets
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container_title	Advanced functional materials
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creator	Cheng, Yi Cui, Guang Liu, Changhao Liu, Zhetong Yan, Longge Liu, Bingyao Yuan, Hao Shi, Pengcheng Jiang, Jun Huang, Kewen Wang, Kun Cheng, Shuting Li, Junliang Gao, Peng Zhang, Xinfang Qi, Yue Liu, Zhongfan
description	Joule heating is featured with an extremely high rising rate of temperature with hundreds of kelvin per second, which has shown superiorities of high efficiency and energy conservation in graphene fabrication. Herein, we design a dynamic joule heating system for continuous synthesis of graphene fibers with ultrashort high‐temperature (≈2000 °C), treating time (≈20 min), and low electric energy consumption (≈2000 kJ m−1). During the joule heating fabrication, the current flowing through the fibers can manipulate the configuration of graphene sheets, the basic component units of fiber, and induce their alignment. Theoretical simulations reveal that graphene sheets tend to rotate towards the current direction under the current induced electric field for the highest stability with the lowest electric free energy and zero rotation torque. Therefore, the electrical and mechanical performances of as‐fabricated graphene fibers can be further improved in comparison with thermally annealed graphene fibers without applying current. A dynamic joule heating system is designed, enabling the ultrafast and continuous fabrication of graphene fibers with a high‐temperature treating time of ≈20 min. Innovatively, the current‐induced electric field is first utilized to adjust the conformation order of graphene sheets and thus improves the electrical and mechanical properties of as‐fabricated graphene fibers.
doi_str_mv	10.1002/adfm.202103493
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Herein, we design a dynamic joule heating system for continuous synthesis of graphene fibers with ultrashort high‐temperature (≈2000 °C), treating time (≈20 min), and low electric energy consumption (≈2000 kJ m−1). During the joule heating fabrication, the current flowing through the fibers can manipulate the configuration of graphene sheets, the basic component units of fiber, and induce their alignment. Theoretical simulations reveal that graphene sheets tend to rotate towards the current direction under the current induced electric field for the highest stability with the lowest electric free energy and zero rotation torque. Therefore, the electrical and mechanical performances of as‐fabricated graphene fibers can be further improved in comparison with thermally annealed graphene fibers without applying current. A dynamic joule heating system is designed, enabling the ultrafast and continuous fabrication of graphene fibers with a high‐temperature treating time of ≈20 min. 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subjects	component units conformation order Continuous fibers electric current aligning Electric fields Energy consumption Free energy Graphene graphene fibers joule heating Materials science Ohmic dissipation Resistance heating Sheets
title	Electric Current Aligning Component Units during Graphene Fiber Joule Heating
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