Scalable one-step wet-spinning of graphene fibers and yarns from liquid crystalline dispersions of graphene oxide: Towards multifunctional textiles

JALILI, R., ABOUTALEBI, S.H., ESRAFILZADEH, D., SHEPHERD, R.L., CHEN, J., AMINORROAYA YAMINI, Sima, KONSTANTINOV, K., MINETT, A.I., RAZAL, J.M. and WALLACE, G.G. (2013). Scalable one-step wet-spinning of graphene fibers and yarns from liquid crystalline dispersions of graphene oxide: Towards multifunctional textiles. Advanced Functional Materials, 23 (43), 5345-5354.

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Official URL: http://onlinelibrary.wiley.com/doi/10.1002/adfm.20...
Link to published version:: 10.1002/adfm.201300765

Abstract

Key points in the formation of liquid crystalline (LC) dispersions of graphene oxide (GO) and their processability via wet-spinning to produce long lengths of micrometer-dimensional fibers and yarns are addressed. Based on rheological and polarized optical microscopy investigations, a rational relation between GO sheet size and polydispersity, concentration, liquid crystallinity, and spinnability is proposed, leading to an understanding of lyotropic LC behavior and fiber spinnability. The knowledge gained from the straightforward formulation of LC GO “inks” in a range of processable concentrations enables the spinning of continuous conducting, strong, and robust fibers at concentrations as low as 0.075 wt%, eliminating the need for relatively concentrated spinning dope dispersions. The dilute LC GO dispersion is proven to be suitable for fiber spinning using a number of coagulation strategies, including non-solvent precipitation, dispersion destabilization, ionic cross-linking, and polyelectrolyte complexation. One-step continuous spinning of graphene fibers and yarns is introduced for the first time by in situ spinning of LC GO in basic coagulation baths (i.e., NaOH or KOH), eliminating the need for post-treatment processes. The thermal conductivity of these graphene fibers is found to be much higher than polycrystalline graphite and other types of 3D carbon based materials.

Item Type: Article
Research Institute, Centre or Group: Materials and Engineering Research Institute > Engineering Research
Identification Number: 10.1002/adfm.201300765
Depositing User: Sima Aminorroaya Yamini
Date Deposited: 25 Jul 2017 13:53
Last Modified: 25 Jul 2017 13:53
URI: http://shura.shu.ac.uk/id/eprint/15954

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